WO1996036749A1 - Procedimiento para la proteccion frente a la corrosion externa en intercambiadores de calor a base de cobre - Google Patents
Procedimiento para la proteccion frente a la corrosion externa en intercambiadores de calor a base de cobre Download PDFInfo
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- WO1996036749A1 WO1996036749A1 PCT/ES1996/000105 ES9600105W WO9636749A1 WO 1996036749 A1 WO1996036749 A1 WO 1996036749A1 ES 9600105 W ES9600105 W ES 9600105W WO 9636749 A1 WO9636749 A1 WO 9636749A1
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- alloy
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Classifications
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- C—CHEMISTRY; METALLURGY
- C23—COATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; CHEMICAL SURFACE TREATMENT; DIFFUSION TREATMENT OF METALLIC MATERIAL; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL; INHIBITING CORROSION OF METALLIC MATERIAL OR INCRUSTATION IN GENERAL
- C23C—COATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; SURFACE TREATMENT OF METALLIC MATERIAL BY DIFFUSION INTO THE SURFACE, BY CHEMICAL CONVERSION OR SUBSTITUTION; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL
- C23C10/00—Solid state diffusion of only metal elements or silicon into metallic material surfaces
- C23C10/28—Solid state diffusion of only metal elements or silicon into metallic material surfaces using solids, e.g. powders, pastes
- C23C10/30—Solid state diffusion of only metal elements or silicon into metallic material surfaces using solids, e.g. powders, pastes using a layer of powder or paste on the surface
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- C—CHEMISTRY; METALLURGY
- C23—COATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; CHEMICAL SURFACE TREATMENT; DIFFUSION TREATMENT OF METALLIC MATERIAL; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL; INHIBITING CORROSION OF METALLIC MATERIAL OR INCRUSTATION IN GENERAL
- C23C—COATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; SURFACE TREATMENT OF METALLIC MATERIAL BY DIFFUSION INTO THE SURFACE, BY CHEMICAL CONVERSION OR SUBSTITUTION; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL
- C23C26/00—Coating not provided for in groups C23C2/00 - C23C24/00
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F28—HEAT EXCHANGE IN GENERAL
- F28F—DETAILS OF HEAT-EXCHANGE AND HEAT-TRANSFER APPARATUS, OF GENERAL APPLICATION
- F28F19/00—Preventing the formation of deposits or corrosion, e.g. by using filters or scrapers
- F28F19/02—Preventing the formation of deposits or corrosion, e.g. by using filters or scrapers by using coatings, e.g. vitreous or enamel coatings
- F28F19/06—Preventing the formation of deposits or corrosion, e.g. by using filters or scrapers by using coatings, e.g. vitreous or enamel coatings of metal
Definitions
- the invention relates to a method for protecting copper-based heat exchangers from external corrosion comprising the coating and thermal diffusion of a tin-based alloy on a copper-based core, whereby a composite material is formed that exhibits excellent corrosion behavior.
- the invention also relates to said composite material, fins for heat exchangers constituted by said material and heat exchangers incorporating such fins, as well as to its manufacturing process.
- Heat exchangers in particular, radiators intended for cooling engines in automobiles and agricultural and industrial machinery (thermal engines) consist of a central core, called a honeycomb, formed by a set of tubes for the circulation of the coolant, and of fins, in contact with the tubes to effect thermal exchange.
- the radiator is completed by tanks and collector plates that close the coolant circuit. Additionally, steel side supports are included in order to increase its rigidity.
- the honeycomb tubes are brass, the fins are copper (Cu) and the tube-fin joint is made by tin-based welds (Sn).
- Sn tin-based welds
- the contribution of the Sn-based weld is made from the brass tube, which has been previously coated by welding, mainly by immersion in a molten solder bath.
- Welding of the honeycomb can be carried out in continuous or static furnaces with an oxidizing environment. Normally, the welding of the honeycomb is carried out in two stages, a first in oven, in which the tubes are welded to the fins, and a second in which the ends of the tubes are welded to the collector plates by means of systems such as capillarity (immersion in molten Sn baths), Sn projection, etc.
- a welding "flux” (or stripper of the metals to be joined and protector of the weld itself during operation) must be applied, either by immersion of the honeycomb or by projection of the flux on the honeycomb.
- the flux that are commonly used are those of a mineral nature that contain inorganic halides, such as zinc and ammonium chlorides, hydrochloric acid, etc. , although other fluxes of mixed nature are also used, with organic and inorganic components, such as hydrochlorides and amines hydrates, hydrobromic acid, etc.
- Another additional problem posed by current radiator manufacturing procedures refers to the application of anti-corrosion protection, since, at present, this operation is carried out, once the manufacture of the radiator is finished, by applying an anti-corrosion paint. projection corrosion, so that only the external areas of the radiator are covered with paint but the honeycomb core is not covered. Normally, the paint penetrates so only, about 2 mm on each face of the honeycomb.
- copper radiators have excellent performance in terms of thermal transfer, mechanical resistance and internal corrosion.
- external corrosion resistance is problematic.
- the main mechanisms that produce corrosion in tubes and fins have been identified, which has allowed the creation of a new material, in particular, a composite material, suitable for manufacturing fins or interleavers, which presents an excellent behavior against corrosion, preserving its thermal and mechanical properties, which also allows reducing the traditional thicknesses of these pieces.
- the composite material provides very effective protection against perforating corrosion that occurs in the radiator honeycomb tubes as a result of the corrosion mechanisms that occur in copper radiators manufactured with current technology. All this guarantees the preservation of the functional characteristics of a radiator, manufactured in accordance with the teachings of the present invention, during long-term service, as has been demonstrated through an extensive program of accelerated corrosion tests.
- the new material provided by this invention consists of a Cu-based core, an intermediate layer consisting of Cu-Sn alloys of variable composition and an external surface formed, essentially, by an alloy based on Sn.
- This material can be obtained by thermal diffusion, under controlled conditions, of a coating with Sn-based alloys deposited on the Cu-based core.
- this new material involves a series of changes in the manufacturing process of the radiators, one of which lies in the possibility of welding the honeycomb in controlled atmosphere furnaces. Operating under these conditions and due to the favorable weldability characteristics provided by the new material, welding can be performed without the use of any type of flux, which is impossible to achieve with current technologies. This way of welding the honeycomb provides great environmental improvements since no gaseous effluents or aqueous contaminants are produced and, at the same time, significant reductions in energy consumption are obtained.
- honeycombs built with this new The material can also be welded in an oxidizing atmosphere furnace, although in this case a non-corrosive organic flux can be used, which does not need washing, thus achieving significant advantages over current radiator manufacturing technology.
- Figure 1 is a photograph showing perforating corrosion in a honeycomb brass arsenical tube [Cu-Zn 70/30, As 0.03%], after 92 hours of salt spray test, at a scale of 20 / one. In the photograph, the leak zone has been indicated by an arrow.
- Figure 2 is a photograph showing perforating corrosion in a honeycomb brass arsenical tube [Cu-Zn 64/36, As 0.03%], after 120 hours of salt spray test, at a scale of 20 / one. In the photograph, the leak zone has been indicated by an arrow.
- Figure 3 is a photograph showing intercrystalline corrosion and disinfication in a honeycomb brass arsenical tube [Cu-Zn 67/33, As 0.03%], as well as corrosion in Sn-Pb welding, after 144 hours of salt spray test, at a scale of 390/1 ( Figure 3A) and at a scale of 325/1 ( Figure 3B).
- Figure 4 is a photograph showing corrosion by disinfication in a honeycomb tube, from brass to phosphorus [Cu-Zn 66/34 P], after 244 hours of salt spray test, at a scale of 260/1 ( Figure 4A), as well as perforating corrosion (intercrystalline and decay) in said honeycomb tube after 244 hours of salt spray test, at a scale of 260/1 ( Figure 4B).
- Figure 5 is a photograph showing corrosion on a fin after 144 hours of salt spray test, at a scale of 260/1 ( Figure 5A), as well as at a scale of 360/1 ( Figure 5B).
- the photograph shows the union of the honeycomb tube to the fin.
- the honeycomb tube is formed by arsenical brass [Cu-Zn 67/33 As 0.03%] and the fin by Cu-Sn (0.1% Sn).
- Figure 6 is a photograph showing the appearance of the honeycomb of a radiator incorporating fins made of a composite material provided by this invention, after 1,170 hours of salt spray test (0.5x [0.5X]).
- Figure 7 is a photograph showing an enlarged detail of Figure 6 (2X).
- Figure 8 is a photograph showing the appearance of the tube after 1,008 hours of salt spray test (5X). As can be seen, no corrosion attacks on the brass are noticed and the Sn-Pb film is preserved on the base metal.
- Figure 9 is a photograph showing the appearance of a section of the tube after 1,008 hours of salt spray test (1,000X).
- the Cu-Sn alloy film can be seen on the surface of the brass, but no corrosion points are observed.
- Figure 10 is a photograph showing the appearance of a section of a fin, made of a material provided by this invention, after 1,008 hours of salt spray test (1,000X). By examination with the optical microscope, the Cu core and the Cu-Sn alloy film of approximately 1 to 2 ⁇ m can be seen over the entire surface of the fin.
- Figure 11 is a photograph showing the appearance of the tube-fin junction after 1,008 hours of salt spray test (100X). It can be seen that there is a slight attack of Sn-Pb welding, but an appreciable meniscus is preserved.
- Figure 12 is a photograph showing an enlarged detail of Figure 16 (200X).
- Figure 13 is a photograph showing the appearance of a honeycomb containing fins made of a material provided by this invention and welded in a static oven, under vacuum, under pressure of N 2 and without using any type of flux.
- the method for protection against external corrosion in copper-based heat exchangers, especially in radiators intended to cool thermal engines, more particularly, automobile radiators comprises the coating and thermal diffusion of a base alloy. of tin on a copper-based core, thereby forming a composite material that has excellent corrosion performance.
- the perforation point corrosion mechanism produced in the honeycomb tubes (brass) manufactured according to prior art procedures is eliminated and the corrosion in the welds and fins is significantly reduced. All these corrosion processes entail a great decrease in the functional characteristics of heat exchangers and particularly in automobile radiators, since, although perforating corrosion in the honeycomb tubes renders the radiator useless, the fin and corrosion of the fins Welds cause significant losses in the thermal and mechanical characteristics of the radiator.
- the invention provides a method for the protection of heat exchangers comprising the formation of a new composite material, suitable for the manufacture of fins for heat exchangers, consisting of a core based on Cu, an external surface consisting of an alloy based on Sn and an intermediate layer consisting of Cu-Sn alloys of variable compositions, obtained by coating and thermal diffusion, under controlled conditions, of an alloy based on Sn deposited on the core based on Cu.
- this invention provides a method for protection against external corrosion in copper-based heat exchangers characterized in that a) a coating with an Sn-based alloy is applied on a Cu-based core; and b) the Cu-based core coated with the Sn-based alloy is subjected to a suitable heat treatment, under controlled conditions, aimed at causing the thermal diffusion of said alloy in said Cu-based core, in case said thermal diffusion has not taken place simultaneously with the application of the coating, thus forming a composite material that is constituted by a core based on Cu, an external surface consisting of an alloy based on Sn and a layer intermediate consisting of Cu-Sn alloys, of variable compositions, which guarantee total adhesion and continuity of the different layers of the composite material.
- core based on Cu refers to a material constituted mainly and mainly by Cu which, optionally, may be weakly alloyed with one or more metals, selected from the group formed by, for example, Te, Mg, Zn , Sn, Cd, Cr, Ag, Pb, In, Be, Zr, Fe, P, Al and Ni, which, as a whole, may be present in a concentration of less than 0.2% by weight.
- metals selected from the group formed by, for example, Te, Mg, Zn , Sn, Cd, Cr, Ag, Pb, In, Be, Zr, Fe, P, Al and Ni, which, as a whole, may be present in a concentration of less than 0.2% by weight.
- These elements added to the Cu are intended to increase the thermal resistance of the Cu so that its mechanical properties are maintained after the thermal welding cycles of the honeycomb. At the same time, these elements allow to guarantee the values with the highest possible thermal conductivity in order to achieve the most adequate radiator performance.
- Sn-based alloys includes pure Sn and any alloy of Sn with other metals.
- preferred Sn-based alloys, used to prepare the composite material of this invention comprise: a) Binary Sn-Pb alloys, in any proportion, preferably, in a proportion comprised between 1% and 99% in Sn and 99% and 1% in Pb; b) Sn-Pb alloys with the addition of other elements, such as Sb, Ag, Cu, Zn, Bi, Cd, In, Ni, Pb, in the following proportions:
- Sn 0.5 to 99%
- Sb 0.01 to 7% Ag: 0.01 to 5%
- Cu 0.01 to 2%
- Zn 0.01 to 1%
- Bi 0.01 to 2%
- Cd 0.01 to 5%
- Ni 0.01 to 1%
- Pb 0.5 to 99%
- Sn-Sb alloys in a proportion between 93% and 99.5% in Sn and 7% and 0.5% in Sb
- Sn-Ag alloys in a proportion between 95% and 99% in Sn and 5% and 1% in Ag
- Sn-Zn alloys in a proportion between 97% and 99% in Sn and 3% and 1% in Zn
- Pure Sn with a minimum percentage of Sn of 99%.
- Sn-based alloys have an anodic electrochemical potential against the Cu-based nucleus, which allows effective protection of the Cu against aggression caused in natural or artificial media containing, among other compounds, inorganic chlorides, nitrogen compounds and sulfur oxides, which significantly increases the life of the radiator fin and reduces the thickness and weight of the radiator, by achieving adequate conservation of the mechanical and thermal properties of the fins.
- the composite material formed must have a minimum thickness of 1 miera ( ⁇ m).
- said thickness is determined by the sum of the thickness of the intermediate layer, constituted by the alloys of Cu-Sn of variable composition, and the thickness of the external surface, constituted by the alloy based on Sn. Because the corrosion protection increases with the coating thickness, the most convenient thickness can be modulated to obtain a certain level of protection.
- the thickness of the intermediate layer and the outermost surface should be between 1 ⁇ m and 1/5 of the total thickness of the composite material, including the thickness of the core based on Cu. In practice, it has been observed that a total thickness between 2 and 4 ⁇ m provides good results.
- the manufacture of the composite material comprises the coating of the core based on Cu with an alloy based on Sn and the thermal diffusion of said alloy deposited on the core based on Cu.
- the deposit or application of said Sn-based alloy on the Cu-based core can be carried out by various procedures.
- the coating of the core can be carried out by immersion of said Cu-based core, in continuous, in a bath of a molten Sn-based alloy, the coating layer being regulated by means of an air jet, an inert gas, water or lamination. In this case, the thermal diffusion of the alloy occurs simultaneously to the core coating.
- said coating can be made by projection of the molten Sn alloy, by wave or by cascade, on the Cu-based core.
- the thermal diffusion of the alloy also occurs simultaneously to the coating of the core with said alloy.
- the coating can be carried out by depositing a metal powder comprising pure Sn or the Sn-based alloy, or pastes containing a metal powder comprising pure Sn or the Sn-based alloy, onto the Cu-based core, followed by a heat treatment at a temperature equal to or greater than 300se so that the thermal diffusion of the alloy over the Cu-based core takes place.
- the coating of the Cu-based core with the Sn-based alloy can be performed by electro-deposition of pure Sn or Sn-based alloys on the Cu-based core, followed by thermal diffusion at an equal temperature or greater than 300P-C.
- the coating with the Sn-based alloy can be applied on a Cu-based core in the form of a band and with the appropriate thickness for the manufacture of fins for heat exchangers, or alternatively, it may have a thickness greater than that necessary for the manufacture of such fins, in which case, a lamination stage of the composite material once formed can be carried out until obtaining the thickness suitable for the manufacture of fins.
- the Sn-based alloy can be applied on the fins constructed from uncoated Cu bands and also on a conventional honeycomb constructed with brass tubes and Cu fins.
- the coating of the Cu-based core with the Sn-based alloy may be total or partial.
- the partial coating can be carried out, preferably, by electrolytic deposition of pure Sn or of the Sn-based alloy, or by projection of the molten Sn-based alloy, or by depositing either a metallic powder containing Pure Sn or the Sn-based alloy, or of pastes containing a metallic powder comprising pure Sn or the Sn-based alloy, over the area of the Cu-based core to be coated, followed by thermal diffusion at a temperature equal to or greater than 300se
- the coating can be applied either over the entire honeycomb or on its external surfaces.
- the coating can be applied so that it only affects the outer areas of the honeycomb and not the core of the honeycomb.
- the composite material may not be present over the entire width of the fins but may cover only the anterior and posterior surfaces of the honeycomb, at a depth of up to 1/3 of the width of the honeycomb.
- the partial coating can be carried out on the surfaces to be covered, preferably, by electrolytic deposition of pure Sn or of the Sn-based alloy, by projection of either the molten Sn or the molten Sn-based alloy, or by depositing either a metallic powder containing pure Sn or the alloy based on Sn, or pastes containing a metallic powder comprising pure Sn or the alloy based on Sn, on the surface of the honeycomb to be covered, followed of thermal diffusion at a temperature equal to or greater than 3002C.
- the solderability conditions of the honeycomb, provided by the composite material of the fins are much more favorable, since said composite material, thanks to its intermediate layer based on alloys Cu- Sn and its external surface based on Sn, has a very improved weldability with respect to the usual material used based on Cu.
- This allows the use of welding flux consisting of organic acids, amines and resins, without inorganic components. Therefore, the conditions of the welding process are much smoother and the washing and drying operations of the honeycombs are also suppressed.
- the welding of the honeycomb can be carried out in non-oxidized controlled atmosphere furnaces, whereby the welding operation is carried out without any flux, which greatly simplifies the manufacturing process of the heat exchanger since the facilities are eliminated of fluxing, washing and drying.
- this technology also contemplates the possibility of welding the ends of the tubes to the collector plates in the same operation of welding the tubes to the fins. For this, it is enough to apply a Sn-based solder locally, without flux or including a very weak, non-corrosive organic flux, which does not cause any environmental problems.
- alcoholic rosin solutions can be mentioned, not activated or activated with organic acids or amines, for example, rosin: isopropanol (10:90), rosin: glutaic acid: isopropanol (10: 2: 88 ) or rosin: dibutylamine hydrochloride: dimethylamine hydrochloride: isopropanol (10: 2: 4: 84).
- a further object of this invention is a process for the manufacture of copper-based heat exchangers, especially radiators for cooling thermal motors, and more particularly automobile radiators, in which the fins are composed or totally coated. or partially, by the composite material provided by this invention, which includes a welding stage of the tubes to said fins, which can be carried out: a) in a continuous or static oven with an oxidizing atmosphere, using a non-corrosive organic welding flux that does not need washing, consisting of organic acids, amines and resins, without inorganic components; or alternatively, b) in a non-oxidizing controlled atmosphere furnace, without the incorporation of any type of flux.
- furnaces can be either vacuum, continuous or static furnaces or inert, continuous or static furnaces, with the presence of inert gases, such as N 2 , C0 2 , and other inert gases, and absence of 0 2 and H 2 0.
- inert gases such as N 2 , C0 2 , and other inert gases
- Another additional object of this invention is fins for heat exchangers, especially suitable for use in the manufacture of radiators for the cooling of thermal motors, such as automobile radiators, essentially constituted by the composite material provided by this invention.
- Said fins can be manufactured by coating and thermal diffusion of an alloy based on Sn on a Cu-based core in the form of a band and with the thickness suitable for the manufacture of the fins, or alternatively, it can have a thickness greater than that necessary for the manufacture of such fins, in which case, a lamination stage of the composite material once formed can be carried out until the thickness suitable for the manufacture of fins is obtained.
- such fins are manufactured from a Cu-based core, in the form of a fin and of the appropriate thickness, on which a coating with an alloy based on Sn is applied over the entire surface of the fin or outer strips of said fin, by the application of preformed sheets, wires or cords of Sn alloys, or by electro-deposition of pure Sn or of the Sn-based alloy, or by projection of the alloy to molten Sn base, or by depositing well of a metallic powder containing pure Sn or an alloy based on Sn, or pastes containing a metallic powder comprising either pure Sn or an alloy based on Sn, followed by thermal diffusion at a temperature equal to or greater than 300 ° -C.
- coating said fin consisting of a core based on Cu
- coating said fin can be done by 'immersion in a molten bath of an alloy based on Sn, by spraying the pure Sn molten or laea Terms Sn - based, by wave or by waterfall, of the Cu-based core or of the surface strip to be coated, with thermal diffusion simultaneous to the coating.
- Another additional object of this invention is a copper-based heat exchanger, such as a radiator intended to cool a thermal engine, more particularly a car radiator, which contains fins manufactured entirely or partially with the composite material obtained by the procedure of this invention.
- the invention also provides a method for depositing Sn-based alloys on the honeycomb of a copper-based heat exchanger, manufactured with the technology pertaining to the state of the art, that is, formed by brass tubes and fins of copper, characterized in that said alloy is applied on the honeycomb so that it mainly covers the outer fringes of the fins, by electro-deposition, applied on the two faces of the honeycomb, either pure Sn or alloys based on Sn , or by spraying either a metallic powder containing pure Sn or an alloy based on Sn, or pastes containing a metallic powder comprising pure Sn or an alloy based on Sn, followed by thermal diffusion at an equal temperature or higher than 300SC.
- Cu-Sn bands (0.1% Sn) 0.042 mm thick are They were continuously coated with an alloy of Sn-Pb (15% Sn + 85% Pb), in a molten bath and with a coating thickness of 2 ⁇ m / face. With the material obtained, fins for automobile radiators were manufactured and radiators including such fins were mounted. The honeycomb welding was carried out in a continuous oven, with an oxidizing atmosphere, using an organic flux ' . Thermal diffusion was achieved by coating the band with the molten Sn alloy.
- Cu-Cd bands (0.2% Cd) 0.04 mm thick were continuously coated with a molten Sn-Pb alloy (25% Sn + 75% Pb), by immersion in a molten bath, and with a coating thickness of 4 ⁇ m / face.
- a molten Sn-Pb alloy (25% Sn + 75% Pb)
- fins for automobile radiators were manufactured and radiators including such fins were mounted.
- the honeycomb welding was carried out in a continuous oven, with an oxidizing atmosphere, using an organic flux. Thermal diffusion was achieved by coating the band in the molten Sn alloy.
- Figures 8 to 12 by comparison with Figures 1 to 5 corresponding to radiators constructed with the technology belonging to the prior art, subjected to a salt spray test in short duration tests (less than 244 hours) and in those that have produced very intense corrosion, show the greater resistance to external corrosion of the copper radiators treated with the protective process of the present invention.
- EXAMPLE 3 Fins were made from a Cu band coated by an Sn-Pb alloy (60/40), by aqueous phase electrolysis. After performing the electrodeposition, a thermal diffusion treatment was carried out at 300SC for 30 seconds. Subsequently, radiators were built that included the fins described above. The honeycomb welding was performed in a static vacuum oven. The radiators were subjected to a continuous test of acetic salt mist, containing CuCl 2 - CASS TEST - according to ASTM B 368. When the radiator was examined, no major corrosion was observed in the tubes, in the fins or in the meniscus of welding. EXAMPLE 4
- a radiator honeycomb was constructed containing fins manufactured using a composite material provided by this invention provided with a film of Sn-Cu and Sn alloys of 3 ⁇ m total thickness. The welding was carried out in a static oven, under vacuum and under a nitrogen pressure of 40 mbar. No type of flux was used.
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Abstract
Description
Claims
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
EP96915036A EP0771888A1 (en) | 1995-05-16 | 1996-05-14 | Process for the protection against external corrosion in copper-based heat exchangers |
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
ES9500935A ES2129282B1 (es) | 1995-05-16 | 1995-05-16 | Procedimiento para la proteccion frente a la corrosion externa en intercambiadores de calor a base de cobre. |
ESP9500935 | 1995-05-16 |
Publications (1)
Publication Number | Publication Date |
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WO1996036749A1 true WO1996036749A1 (es) | 1996-11-21 |
Family
ID=8290367
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
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PCT/ES1996/000105 WO1996036749A1 (es) | 1995-05-16 | 1996-05-14 | Procedimiento para la proteccion frente a la corrosion externa en intercambiadores de calor a base de cobre |
Country Status (3)
Country | Link |
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EP (1) | EP0771888A1 (es) |
ES (1) | ES2129282B1 (es) |
WO (1) | WO1996036749A1 (es) |
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1995
- 1995-05-16 ES ES9500935A patent/ES2129282B1/es not_active Expired - Lifetime
-
1996
- 1996-05-14 WO PCT/ES1996/000105 patent/WO1996036749A1/es not_active Application Discontinuation
- 1996-05-14 EP EP96915036A patent/EP0771888A1/en not_active Withdrawn
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EP0008706A1 (de) * | 1978-08-29 | 1980-03-19 | Joh. Vaillant GmbH u. Co. | Mit einer Bleilegierung überzogener Wärmetauscher für eine brennstoffbeheizte Wärmequelle und Verfahren zum Verbleien eines solchen Wärmetauschers |
JPS5777894A (en) * | 1980-10-31 | 1982-05-15 | Tsuchiya Mfg Co Ltd | Manufacturing of heat exchanger |
JPS5864498A (ja) * | 1981-10-13 | 1983-04-16 | Matsushita Electric Ind Co Ltd | 熱交換器用表面処理材 |
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Also Published As
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ES2129282A1 (es) | 1999-06-01 |
MX9700433A (es) | 1998-07-31 |
EP0771888A1 (en) | 1997-05-07 |
ES2129282B1 (es) | 2000-05-16 |
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