DE1182939B - Flux for soldering with hard solders - Google Patents

Description

Fluxes for brazing with brazing alloys Fluxes are used when brazing and brazing used to oxidize the heated metal surfaces and the solder -prevent yourself and the metal surfaces from any stains or contamination to clean, which are disadvantageous for the free spread of the solder. Slides flux combines during soldering with the unwanted products during the soldering process, which would worsen the soldering or prevent it completely, it loosens it, inhibits its Effect or otherwise render them ineffective. Flux of the present Invention enclosed type are usually od by means of brushes. The like. In the form a film is applied to the areas where the molten solder will spread target; but they can also be fed to the solder itself. To the brazing alloys, which are used for joining metals and for which the invention Flux is intended to include solders that melt in the range of 371 to 1093 ° C, z. B. silver or other brazing alloys.

Those generally used for the brazing alloys described above Fluxes are mainly alkali borates and fluorides. Such fluxes result however, if you heat for a long time or work at elevated soldering temperatures must, no really satisfactory soldered connections. It has been shown that under these conditions the flux currently used does not control the Oxide formation result.

It is known from German Patent 376 758 that one Instead of the flux borax, use, for example, sodium or phosphorus copper can, but this solution is not satisfactory either, since z. B. that embedded in the plumb Sodium is dangerous to handle at the high soldering temperatures.

According to the German patent specification 512 879 one uses as solder amorphous phosphorus. However, this phosphorus does not meet the requirements of a flux Requirements. The binding effect of phosphorus is much more on education attributed to phosphorus alloys.

The reference contained in German Patent 381848 that according to German patent specification 125 634 borax by its components boric acid and can replace metallic sodium, only serves to form boric acid Sodium as a flux before the solder flows. Otherwise, goes from the German Patent specification 125 634 shows that not metallic sodium, but a sodium salt is meant, from which sodium borate is produced in the presence of boric acid. A such sodium salt is e.g. B. sodium carbonate.

It is also known from German patent application S 24662 VIa / 49 h a welding electrode with a basic, in particular lime-based cover, which Contains boron or boron compounds in the coating compound to reduce the amount of material that occurs during welding To prevent the development of odorous gases.

Also from the German interpretation 1008 993 welding means known as deoxidizing agent silicon, elemental or alloyed, titanium, zirconium, Vanadium, aluminum, magnesium, carbon, borides of manganese, borides of iron and / or may contain borides of calcium.

However, the technique of welding and soldering or brazing only touches one another in that both processes aim to join metals with one another, but with the use of completely different measures. Brazing differs from all welding processes in that a non-ferrous metal with a melting point of around 4251 C, which is below that of the base material, must be used. This deep melting solder is distributed between the joint surfaces of the workpiece by capillary forces (see the definition of brazing in the "Welding Handbook", 3 = d Edition, 1950, published by the American Welding Society). The need to distribute the solder between the joining surfaces of the workpieces by capillary forces makes the technique of brazing completely different from welding. When brazing, the connection and the Parts by weight Fluorine (addition in the form of a compound, z. B. of salts, such as acidic potassium fluoride) 1.8 Alkali metal (additive in the form of a compound dung, e.g. B. of salts such as potassium penta- or potassium tetraborate). . . . . . . . . . . . . . . . 2.5 Boron (addition in the form of a compound, z. B. of salts such as boric acid or ca- lium penta- or potassium tetraborate) ..... 1.0 Elemental boron. . . . . . . . . . . . . . . . . . . . . . . . 0.04 adjacent surfaces of the workpiece are heated in their entirety or over a substantial area before the solder is allowed to flow in to fill the joint. Local or progressive heating, application of pressure or melting of the base material, as is the case with many welding processes, is completely absent in brazing. Welding is the term used to describe the union of the same or similar materials in such a way that the welding point and base material together form a whole that is as homogeneous and equivalent as possible.

Due to the different welding and Brazing, the flux used for the process are also completely different. Soldering fluxes are used to remove the workpiece surfaces to be joined, between which the solder is then introduced to make perpendicular. That Flux also has the task of cleaning the surface during heating and soldering to protect and prevent thermal radiation. If in a welding process Flux is required, it is generally used with the welding rod, and it affects the melting and flow properties of the metal of the metal electrode.

The invention aims to provide a flux that under adequate protection of the metal surfaces under the soldering conditions specified above results in the free and unhindered flow of brazing alloys, solid connections results in the wetting of the surfaces of the parts to be united by the soldering material supports and that has the property of not even with long-term storage to decompose.

There is no one universal flux that works for everyone Hard solutions are equally well suited, and accordingly there are necessarily different ones Flux compositions for various uses. The American Welding Society (A.W.S.) has classified these braze compositions into six types. The invention relates to Type No. 3 of this A.W.S. Classification, which thereby is defined as containing one or more of the following components: boric acid, Borates (sodium, potassium, lithium borates, etc.), fluorides (sodium, potassium, lithium fluorides etc.), fluoborates (potassium, sodium fluoborates etc.) and wetting agents, but a fluorine compound must contain. This type of flux will hereinafter become synonymous with that of the person skilled in the art common designation A. W. S. type 3 as "flux of the alkali metal fluoride borate type" designated.

The invention therefore relates to a flux of the alkali metal fluoride borate type for brazing with hard solders, which are characterized by a content of 0.3 to 10% of its Total weight of boron in elemental form or in the form of a water-insoluble one Identifies bondes in a finely divided state.

This flux represents an extraordinary improvement in the known flux. While the borates contained in the known fluxes (e.g. Borax, Na2B407) represent compounds that are already strong with oxygen are saturated, elemental boron possesses at the elevated temperatures t at Brazing work predominates, an extraordinarily strong affinity for oxygen. Accordingly, if boron is the usual alkali metal fluoride borate type flux is added, it gives a substantial increase in the protection of the metal parts against oxidation during brazing. The elemental boron comes in the form of a fine Powder, in particular with a grain size of not more than 200 mesh, is used. Powdered water-insoluble borides (e.g. calcium boride, CaBs) are also effective.

In the preparation of the flux according to the invention, the Fluoride and borate powder or other salts together with the finely divided elemental Boron or a water-insoluble boride with sufficient flux-containing water, to form a paste in which the powdery elemental boron or the powdery insoluble boride is suspended.

It has been found that elemental boron is most effective. The amount, with which excellent results are obtained, is 0.3 to 1.00% by weight of the finished flux. The optimal effect with minimal addition of boron is included about 0.75% boron based on the weight of the finished flux. Water-insoluble Boride is especially used in an amount of 2.5% of the weight of the finished flux used; the maximum amount was empirically determined to be 10%. It was observed that when using a larger amount the flux properties, e.g. B. his Cleaning effect, are adversely affected.

To further explain the alkali metal fluoride borate type fluxes and the novel flux according to the invention is approximate below Composition of a preferred flux indicated. For the production of fluxes a very large number of connections is suitable. These connections are subject to as is known, chemical reactions occur during mixing and also during brazing. As a result, the solution of connections that occurs at the soldering temperature is chemical how physically right from the originally mixed components different.

Examples of some fluxes according to the invention are: Weight percent 1. Potassium tetraborate ............ 39.75 acidic potassium fluoride. . . . . . . . . 59.50 elemental boron. . ........... 0.75 2. Sodium borate ............... 29.75 Boric acid ................... 29.75 acid sodium fluoride .... .... 39.75 elemental boron. . . . . . . . . . . . . 0.75 3. Potassium carbonate ............. 17 Boric acid ................... 32.00 acidic potassium fluoride. . . . . . . . . 48.50 Calcium boride ............... 2.5 Of the as. Flux base known fluxes of the alkali metal fluoride borate type to be used are preferred which contain potassium or sodium as the alkali metal.

The physical or chemical process by which the inventive Flux which gives good results as described above is not exactly known. As described above, the flux of the present invention is capable of oxidation in many ways to a greater extent than the previously known fluxes and prevent the oxides to be removed chemically after their formation. It also increases the surface tension of the molten brazing solder, so that it is free over the brazing temperature heated workpiece surfaces flows.

The results of one of the numerous series of tests carried out are shown in the drawing. In the drawing, F i g. 1 in plan view a sample of a stainless steel plate to which using a ordinary flux, a solder with 45% Ag is melted, and F i g. 2 in Top view of a sample from a stainless steel plate on which this solder is melted with 45% Ag using the flux according to the invention.

On two identical stainless steel samples from 0.8 - 76.2 - 47.6 mm each was a circular solder disk 6.4 mm in diameter and 5.1 mm thick melted. Both samples were heated equally for the same time. As a flux a known paste-like flux was used in these experiments, the consists of a mixture of fluoride and borate salts and under the type designation APW 1200 is sold. In each case the sample was brushed with the flux, the solder disk is placed on the flux and heat is supplied by means of a blowtorch. In the case of the sample according to FIG. 1 flowed the solder disc at arbitrarily strong or prolonged application of heat only to the extent specified, while in the case of the sample according to FIG. 2 the perpendicular flows apart widely, forming a very small edge angle and a 101 / times larger area (10500/0) than the solder disc according to FIG G. 1. The flux according to the invention can thus with longer soldering times and for Find high temperature brazing use. Furthermore, larger parts can by means of of the flux according to the invention can be brazed better and faster. It has has been shown that connections of metal parts using the invention Flux can be produced, in use even the strongest mechanical shocks withstand vibrating loads as well as the highest temperature loads, how they z. B. occur in the stator parts of jet motors and bursting discs, while in other cases where the compounds with the previously known Fluxes were carried out did not give satisfactory results.

The flux according to the invention can be used in any desired manner used, e.g. B. be applied to the metal to be soldered or the solder itself, like by brushing or dipping.

Claims (6)

Claims: 1. Flux of the alkali metal fluoride borate type for brazing with hard solders, characterized by a content of 0.3 to 10% of its Total weight of boron in elemental form or in the form of a water-insoluble one Borids in a finely divided state. 2. Flux according to claim 1, characterized by a content of 0.3 to 1.0%, preferably 0.75% of its total weight elemental boron. 3. Flux according to claim 1, characterized by a content of 2.5% of its total weight of a water-soluble boride. 4. Flux according to claim 2, characterized in that it consists of 39.75% potassium tetraborate, 59.50% acid potassium fluoride and 0.75% elemental boron. 5. Flux according to claim 2, characterized in that it consists of 29.75% sodium borate, 29.750 / a boric acid, 39.75% acidic sodium fluoride and 0.75% elemental boron. 6. Flux according to claim 3, characterized in that it consists of 17% potassium carbonate, 32, Oo / o boric acid, 48.5% acid potassium fluoride and 2.5% calcium boride. Considered publications: German Patent Nos. 381848, 396 758, 512 879; German patent application S 24662 VI a / 49 h ( announced on May 13, 1953); "Chemisches Zentralblatt", 1958, p. 1695 (report on the German Auslegeschrift No. 1008 993).