DE2821538C3 - Solder paste for joining stainless steel objects, in particular pipes - Google Patents

Description

The invention relates to a solder paste, which is used in particular for connecting pipes made of stainless steel can be used.

Brazing stainless steel is relatively difficult. In particular, it causes considerable difficulties make a joint on stainless steel pipes. Such connections are desirable in the case of pipes in which water, hot water or other flowing media are supplied or are conducted, with a high resistance to corrosion and for the pipe connection an absolute seal are desired. Some of the reasons that trouble arises are that following:

1.) Stainless steels are coated with a characteristic oxide film, which is created by that in the steel Chromium contained is formed. This oxide film is tensile and only sparingly soluble. You need a special flux to completely loosen the oxide film during soldering.

2.) The thermal conductivity of stainless steel is rather low and ⁰ C is about 0.126 to 0.25 J / cm S, which is compared to the thermal conductivity of copper which 3.94 J / cm · s ° C, low In this respect, it is not uncommon for the temperature distribution at the pipe joint to be inconsistent during the brazing when conventional brazing processes are used. This results in imperfections in the joints due to the uneven distribution of the molten solder, which tends to flow into the high temperature areas. Therefore, it is extremely difficult to join stainless steel pipes together by brazing without creating large voids and imperfections in the brazed joints. Such defects in the pipes connected to one another by soldering can, however, lead to considerable disadvantages, in particular when water or hot water is guided in the pipes. Namely, these pipes are required to have a high resistance, particularly to high pressure, and there are often disadvantages that durability is reduced and leakage occurs

3.) When soldering stainless steels, it is necessary to use an aggressive flux, containing a metal chloride in combination with hydrochloric acid and the like. This flux is used to remove the sparingly soluble oxide film (Japanese Patent Publications 3 465/1950, 1 114/1963 and 2 787/1968). However, there are flux center pressures cannot be completely removed from the inside of the solder joints this results in a strongly corrosive effect of the flux residues. It results in stainless Steel material] dimple-like rust pitting.

In this respect, it is undesirable to use a chloride-containing flux when soldering stainless steel use.

4.) Non-corrosive fluxes such as phosphoric acid-based or phosphoric acid-based fluxes, which contain a small amount of copper salts or tin salts can be used in one Find soldering method use in which a rod-shaped or wire-shaped solder is used and the solder during the soldering from the end of the rod or wire into the space, which is to be closed (Japanese Patent Publications 2 314/1961, 8421/1961, 15 008/1961 and Japanese Patent 59/1972).

From US Pat. No. 3,597,285 a flux composition is known which is used when soldering stainless steel. This flux contains orthophosphoric acid or phosphorous acid and at least a portion of finely divided copper and copper salts. However, the main component of this known flux is phosphoric acid, and the carbon black contains copper or copper salts as essential components. Because of the low activation temperature range of such non-corrosive fluxes and the low thermal conductivity of stainless steel, the pipe connections made by soldering have large voids and defects. It is very difficult to find the most suitable point in time during which the solder should be delivered to the joint.
5.) It is also difficult to obtain the proper accuracy in shape and size in stainless steel pipes. Lies causes difficulties during installation. This is due to the characteristic mechanical properties of the steel, such as poor deformability and rebound when machining the stainless steel. In this respect, it is difficult to find a suitable gap on the order of 0.1 to 0.2 mm and small at the joint To achieve tolerances.

It is characteristic of the molten solder. that it goes deep into the pipe joint. When the gap is on def connection point is dimensioned too wide or varies, voids and other defects arise when soldering, The quality of the pipes connected by soldering is impaired as a result.

Conventional soldering of pipe connections uses a material that is relatively easy to solder can be, for example

Copper and the like. Two different methods are used: One method is that a Flux, which is applied to the surfaces of a joint to be joined, on Soldering temperature is brought, and at this temperature a solder alloy on the areas to be connected the connection point is applied. The other method is to apply a flux to the connecting points is applied, then a solder alloy between the surfaces to be connected is arranged, which happens at the temperature of the environment, and then by heating The soldering is carried out for the reasons given above, however, when connecting of stainless steel pipes through which water or hot water is to be passed than before not proven sufficiently.

That is why another method has been proposed, in which on the one to be connected Surfaces of the stainless steel pipes a copper-nickel or Sn-Pb coating is applied and then the pipes are joined together using a copper joint. This procedure has However, it has not been accepted in practice because of the various, relatively complicated processing steps are necessary and the effort is therefore considerable

In addition, a process for brazing of stainless steel pipes is known for example from US-Pattntschrift 39 63 162, without an additional copper generating compound provided here u>. Connections are obtained which are essentially free of defects and voids. The soldering paste, which is used in this process, contains a flux that consists mainly of phosphoric acid and ammonium dihydrogen sphat as well as a solder powder made of an Sn-Pb alloy. The soldering paste is applied to the surfaces of the stainless steel pipes to be connected, the gap at the connection point being 0.05 to 1.0 mm.

The solder paste is melted by heating, and there is then an additional one immediately afterwards Solder alloy in wire form is introduced into the gap at the connection point (in the following, this process is called two-step soldering). The two-stage soldering has proven itself in practice as exposed enough to be stainless steel pipes in which water or hot water is carried, to connect with each other. This has the following advantages:

50

(1) The stainless steel pipes can be made using simple heating devices such as by infrared radiation, by resistance heating using a blowtorch or a gas burner or the like., are soldered.

(2) The chromium oxide film on the stainless steel can be easily peeled off and leaves an activated one Surface at soldering temperature.

(3) After completion of the soldering, there is no residue of corrosive halides on the stainless steel, such as metal halides, hydrochloric acid, ammonium chloride and the like.

(4) A sufficient connection point is obtained that is void-free and flat, with a Flux based on non-corrosive phosphorus * acid is used with an activation star temperature in a narrow range.

(5) It is possible to use the connecting surfaces on the

Heat pipe joint uniformly and activate it, so that also soldering on relatively wide Columns with a width of 0.05 to 1.0 mm can be made.

In this respect, the above-mentioned US patent is initially sufficient for practice Connection method indicated by soldering for stainless steel pipes. The solder paste, "velche is used, has a composition of 20 to 80 wt .-% flux and 80 to 20 wt .-% Alloy solder powder. The flux has - based on the total weight of the flux - one Composition of 5 to 50% by weight phosphoric acid (H3PO4), 95 to 50% by weight ammonium hydrogen phosphate (NH4H2PO4) and from 0 to 20% by weight other additives such as water, alcohols, glycols and the like

Using solvents such as water or alcohol as the binder results a solder paste in a creamy state. This state is maintained for a certain period of time, and during this time you can apply the solder paste to the surfaces to be connected, for example with a Brush, apply. After a few hours of storage, however, separate due to the relatively low Viscosity, the flux and the solder material. Once in a while a condition arises as when sand is dispersed in water. In this case you have to use the solder paste stir again to bring them to usable condition. When the content of phosphoric acid is too small, it is difficult to apply the solder paste to the surfaces to be joined. This is based on insufficient liability. If the storage time is longer, the flux and solder react with each other, so that the solder paste solidifies and becomes unusable.

In general, the solder that is used when soldering stainless steels wets prefers the surface areas where flux has reacted with the stainless steel. This However, aspiration is different from that of a flux containing phosphoric acid. That's why it is It is important to apply the solder paste uniformly to the surfaces to be connected. When soldering For example, stainless steel pipes will apply the solder paste to the connection surface of the insert Pipe and applied to the connecting surface that receives the inserted pipe. The pipes are then plugged into each other when the solder paste, however, its uniform paste-like state does not retain or if sufficient adhesion is not achieved, there is a risk that the solder coating is peeled off from the surfaces to be connected when the pipes are plugged into one another. To this In this way, numerous voids and flaws arise.

To connect stainless steel pipes together without the risk of creating If defects and voids occur, you need a soldering paste that meets the following requirements:

i) The solder paste has a homogeneous paste-like consistency and can be applied to the surface of the stainless steel can be easily applied.

ii) The solder paste should be spread out slightly as it is applied and have good adhesion, with no lumps in the applied coating Remain,

iii) When stored for a long period of time the paste-like consistency is to be maintained without separating the flux from the solder and without solidification.

The object of the invention is therefore to create an improved solder paste that softens those enumerated above Has properties and can be used in two-step soldering.

To achieve this object, the solder paste according to the invention contains (A) 20 to 80% by weight of flux and (B) 80 to 20% by weight of solder powder, in particular an Sn-Pb solder powder, the flux being based on the total weight of the flux , 20 to 80% by weight of phosphoric acid (H3PO4), 7.5 to 70% by weight of ammonium dihydrogen phosphate (NH ₄ H ₂ PO ₄ ), 0.5 to 10% by weight of copper carboxylate and 2 to 15% by weight / o contains carboxylic acid with at least 8 carbon atoms. Optionally, the flux can also contain up to 30% by weight of glycol ether.

The solder paste of the invention proves relative to the solder paste in US Pat. No. 3,953,162 the application properties, the compatibility of the flux with the solder powder and the stability longer storage advantageous. The improved properties are achieved by modifying the flux achieved, in particular in that the phosphoric acid-containing flux is a carboxamide having 8 or more carbon atoms is added. The flux is paste-like when heated Condition with thixotropy.

The carboxamide with 8 or more carbon atoms is defined as a derivative of an organic carboxylic acid in which the hydroxyl moiety (—OH) is the Carboxyl group

I = C-OH

replaces i ^r t with an amino group. The resulting amide group

shows the acidity associated with the carboxylic acid and not the alkalinity associated with the amine group. Rather, it is essentially neutral. Examples of Carboxamides are the following:

Octanamide (CH, iCH ₂ ) ₆ CONH ₂ ).
Decanamide (CHj (CH ₂ ) SCONH ₂ ),
Dodecanamide (CHi (CH ₂ J _1n CONH ₂ ),
Tetradecanamide (CH ₁ (CH ₂ J ₁₂ CONH ₂ ).
Hexadecanamide (CH ₃ (CH ₂ ) HCONH ₂ ),
Octadecanamide (CH) (CH ₂ ) ^ CONH ₂ ),
9-octadecanamide
(CH) (CHj) ₇ CH = CH (CH ₇ J ₇ CONH ₂ ), etc.

Such carboxamides are / to some extent compatible with phosphoric acid. Addition of these carboxamides to phosphoric acid gives a soft pale. This is great for making a paste-like flux for use in a solder paste.

The composition of the solder paste, soft in the invention to ^one Aliwendung comes Ufid the reasons for their composition "ollen in detail later beschne * ben be

Phosphoric acid is used to melt and reduce the chromium oxide film on the surface of the stainless steel at the soldering temperature. Although the phosphoric acid can be used in a proportion of 40 to 60% by weight, preferably 85 to 86% by weight of the phosphoric acid is orthophosphoric acid. However, it is not intended to use the phosphoric acid alone as the flux component, since the phosphoric acid decomposes immediately when heated to the soldering temperature into methaphosphoric acid and polyphosphoric acid, which do not have sufficient flowability as a flux! exhibit. It is difficult to replace these acids with the molten solder. This disadvantage can be eliminated by combining phosphoric acid with ammonium dihydrogen phosphate in the presence of copper carboxylate. The ammonium dihydrogen phosphate is used in conjunction with phosphoric acid so that the decomposition of the phosphoric acid is suppressed t-nd the flux is heat-resistant at soldering temperature> ^c t The ammonium dihydrogen phosphate decomposes at cot temperature and supplies ammonium, which has a flux effect with the remaining phosphoric acid. Since the decomposition of phosphoric acid to methaphosphoric acid does not appear until the decomposition of the ammonium dihydrogen phosphate is complete, the activation of the flux component is maintained for such a long time , soft to melt the

so added solder, is necessary in this way one gains a sufficient flow of the plumb bob. Since in the invention, the solder paste solder powder in pasty If it contains flux, the solder will melt when heated to the soldering temperature. To that extent

π you don't need flux for thermal stability in as in the case where flux and Solder can be applied separately. The combination of phosphoric acid with ammonium dihydrogen phosphate is particularly suitable for soldering stainless steel pipes with the help of a blowtorch. One wins a good solder coating, and the pipe connection is practically free from defects and voids.

The proportions of phosphoric acid (H3PO4) and ammonium dihydrogen phosphate (NH ₄ H ₂ PO ₄ ) are 20 to

• r, 80% by weight or 17.5 to 70% by weight, ⁰ / - restricted in the case of the invention. The phosphoric acid content is preferably based on 85 to 86% phosphoric acid. This is due to the fact that less than 20% by weight of phosphoric acid accounts for the relative proportion of ammonium dihydrogen phosphate

vi increased. The fluxing is (up to 24O ⁰ C 183) then reduced at the melting temperature of the solder, when heated in such a case to the soldering temperature, the solder is compared with the stainless steel no konetzungseigenschaft. Rather, discrete ones are formed

v. bead-shaped areas of the solder on the surface of the Steel. If the flux contains more than 70% by weight ammonium dihydrogen phosphate, it will decrease the proportion of phosphoric acid. Although it would then be possible to use the flux due to the presence of the

mi carboxamides by adding the glycol ether In the form of a paste, the paste obtained does not appear uniformly on the surface of the stainless steel with a brush. The solder paste wets, the stainless steel does not. That means that the stainless steel surface repels the solder paste and the brush brushes over it Surface. There is therefore no pipe connection that is completely free from defects. if

on the other hand, the content of phosphoric acid exceeds 80 wt .-%, the applicability of the itself resulting flux improved due to the reduction the content of ammonium dihydrogen phosphate, however, the heat resistance is the resultant Flux impaired by reducing the amount of ammonium dihydrogen phosphate. on in this way it becomes difficult to achieve a solder joint which is essentially free of defects.

In this respect, the proportion of phosphoric acid and aluminum dyhydrogen phosphate is chosen according to the invention specified limits.

The copper carboxylate is added to improve the flow of the solder when soldering. this is based on the fact that the copper carboxylate decomposes at the soldering temperature and forms a copper coating the stainless steel forms. The surface of the stainless steel has been cleaned beforehand.

Other substances are known as constituents of the flux, such as tin dichloride and copper chloride. Stannosulfate, copper sulfate and the like. In this way, deposition of the metal on the surface of the stainless steel is obtained. Chlorides are not desirable, however, as chlorides can cause pitting-like rust pitting on stainless steel. The stannous sulfate and the copper sulfate have an adverse effect on the applicability or flowability of the molten solder. Furthermore, the copper sulfate reacts with the solder and oxidizes the solder. Since the formation of an oxide film on the surface of the solder prevents the solder from wetting the surface of the stainless steel, sufficient soldering will not result in the presence of copper sulfate. It has also been proposed to add a copper-containing additive, such as, for example, basic copper carbonate (CuCO) Cu (OH): · H ₂ O) and copper powder, to the flux. The solder paste, which has such an additive, does not show any additional improvement in terms of wettability compared to such a flux which does not have this additive.

The copper carboxylate which is used in the invention is a copper salt which is produced by Reaction of copper with a carboxyl group. Examples of copper carboxylate are

Copper formate (Cu (HCOO) ₂ ■ 4 H ₂ O),
Copper acetate (Cu (CH, C00) ₂ H ₂ O,
Copper tartrate (CuC ₁ H ₄ Oe 3 H ₂ O) ..
Copper oxalate (CuC ₂ O ₁ · V ₂ H ₂ O) etc.

The copper carboxylate is in a proportion of Oj to 10% w / w based on the weight of the flux added. If the copper carboxylate in one proportion of less than Op% by weight is added, the On the other hand, when the proportion exceeds 10% by weight, the flowability of the solder is not improved you don't get any additional improvements.

The carboxamide has 8 or more carbon atoms. This amide is used to ensure that the solder paste does not separate into flux and solder during storage In addition, the addition of this amide makes it easier to apply the solder paste to the Surfaces lightened with the help of a brush If less than 2% by weight of the amide is added, the properties of the phosphoric acid-based flux do not change. That is, the uniform one Applying the solder paste to the surfaces to be connected is then not improved and the resulting solder paste tends to blend in with flux and solder with high phosphoric acid content separate. If more than 15% by weight of the amide im If flux is present, the flux becomes stiff so that it cannot be applied with a brush. When heated with a blowtorch or with the aid of a gas burner, the is then carburized Flux, and there are large amounts of residual flux on the steel surfaces, which only

to be difficult to eliminate. In this respect, rnan chooses the proportion of the carboxamide in the flux within the range from 2 to 15% by weight and preferably from 3 to 9% by weight. If the carboxamide has less than 7 carbon atoms, leave

A paste-like flux cannot be achieved. A the preferred carboxamide is octadecanamide with 18 carbon atoms.

To improve the flowability and stability of the homogeneous solder paste, 7iinärh <; t aU appear advantageous that one polyethylene glycol, Glycerin, various types of fats and oils, such as palm oil, lanolin, carnauba wax and the like. added instead of the carboxamide. Such additives, however, improve the flowability of the solder paste

> 5 not, even if its in the same proportion as that Carboxamide are added. In addition, the flux carburizes during soldering, so that the solder cannot wet the steel surface. In addition, it is difficult to prepare the leftovers

to remove carburized flux by cleaning. In addition, since various types of fats and oils are incompatible with the phosphoric acid-based flux there is a risk that the solder paste will not remain in a stable, creamy state.

The consistency of the solder paste can be adjusted by adding glycol ether to the flux. In particular, if this is too thick and partially solidifies, even if carboxamide is added due to a higher content of ammonium dihydrogen phosphate and a lower content of phosphoric acid. Glycol ether is preferably added if the phosphoric acid is less than 40% by weight. % is present.
The addition of glycol ether is advantageous if the proportion of phosphoric acid is low, but if more than 40% by weight of phosphoric acid is present in the flux, the addition of glycol ether is not necessary.

Suitable glycol ethers are those which both

contain an ether group as well as a hydroxyl group in one molecule. They are hardly volatile and π. "I compatible with most liquids that contain water. Such glycol ethers are the following:

Ethylene glycol monoethyl ether

(C ₂ H ₅ -O-CAOH),
Ethylene glycol monobutyl ether

(Ah

)
Diethylene glycol monoethyl ether

(C ₂ H ₅ -OC ₂ Hi-OC ₂ HiOH),
Diethylene glycol monobutyl ether

(Ji-C ₄ Ho-OC ₂ Hi-OC ₂ H ₄ -OH) and the like.

The preparation of the solder paste is described below. Predetermined amounts of ammonium dihydrogen phosphate and copper carboxylate are introduced into the είπε mixer and mower and mixed intensively and ground. Predetermined amounts of phosphoric acid and / or glycol ether and carboxylic acid

feamide are heated so that the amide is in the Phosphoric acid is dispersed and the resulting mixture is placed in the mixing and milling machine The resulting mixture of flux is introduced into a predetermined amount of solder powder added, so that the solder paste is formed. It is also possible to use certain amounts of phosphoric acid uH / or glycol ethers as well as carboxamide. so that the amide turns into phosphoric acid dispersed, and pouring the resulting mixture into the mixing and milling machine. The strong A certain amount of solder powder is added to the mixed mass and then a predetermined amount is added Amount of previously mixed and ground ammonium dihydrogen phosphate and copper carboxylate added to the contents in the mixing and grinding machine, so that the solder paste is formed.

It should be noted that the invention does not a specific method of making the solder paste is limited.

The proportions of flux and solder powder are determined so that the solder powder 20 to 80 wt .-% of the Solder paste amounts. Less than 20% by weight of solder material means that the surfaces to be joined are not are covered with sufficient solder. If more than 80% by weight of solder material is used in the paste, the solder paste gets pretty hard. Even if you add the amide in this case, the flowability remains the solder paste affected. Accordingly, the proportion of solder powder is limited to 20 to 80% by weight With regard to the composition of the solder itself, no limitation is imposed on the curve Solder alloys, such as Sn-Pb, Sn-Ag, Sn-Pb-Ag and Sn-Sb can be used. in the Generally, a soft solder is used to join the stainless steel tubes. One Solder alloy with a grain size of less than 0.15 mm can preferably be used.

The invention is based on the following exemplary embodiments. Comparative tests and test results will be explained in detail below. The proportions are given in parts by weight. Phosphoric acid is used in the The following embodiments used an 85% strength phosphoric acid of the first quality.

example 1
Prepare the solder paste

Phosphoric acid (85%) 67 parts by weight

Ammonium dihydrogen phosphate 20 parts by weight

Copper formate 3 parts by weight

Octadecanamide 10 parts by weight

Solder powder (Sn50- Pb50.0.1 mm) 100 parts by weight

The predetermined amounts of ammonium dihydrogen phosphate and copper formate are in a mixed and grinding machine introduced and vigorously mixed Darau.Tiin are predetermined amounts of phosphoric acid and octadecanamide placed in an enamelled container and heated. The amide dissolves Part, and the amide will be in the phosphoric acid dispersed. The resulting mixture is put into the mixing and milling machine in which the mixture is made Ammonium dihydrogen phosphate and copper formate is present, introduced and resulting therefrom resulting mixture is mixed vigorously and ground. A paste-like flux is obtained The predetermined amount of solder powder is added to this and the whole thing is mixed vigorously. You get then the finished solder paste. This has excellent storage properties.

_% Soldering process

Two stainless steel tubes (AlSI 304) with one Outside diameter of 22 mm and a wall thickness of 1 mm are joined together to form a pipe connection, the gap at the junction 0.1 to

ίο is 0.2 mm and the overlap is 16 to 17 mm. Of the Gap at the junction is the difference between the outer diameter of the inner tube and the inner diameter of the outer tube. The pipes are degreased with trichlorethylene, and the

H connecting surfaces are polished with sandpaper. The solder paste used in previous Process stages has been produced, is applied to the surface with the help of a brush. To as the pipes are assembled at their junction, this junction becomes uniform with Heated with the help of a blowtorch. If the flux is boiling and the solder powder has melted in the flux, in Wire form Sn50-Pb50 solder with a diameter of 1.6 mm is introduced into the gap and heated. the Test results of the tubes soldered together in this way are summarized in the table.

The result is a sufficient soldering without defects and voids in the soldering area.

Example 2
Prepare the solder paste

Phosphoric acid (85%) 60 parts by weight

Ammonium dihydrogen phosphate 25 parts by weight

Copper acetate 9 parts by weight

Octadecanamide 6 parts by weight

Solder powder (Sn60-Pb40.0.1 mm) 100 parts by weight

4ö Predetermined amounts of phosphoric acid and octadecanamide are placed in an enamelled container and heated so that the amide partially is dissolved and is dispersed in the phosphoric acid. The resulting mixture is divided into a mix and Introduced grinding machine and a predetermined amount of solder powder is also added. These Portions are then vigorously mixed together and ground. Thereupon certain proportions of Crush ammonium dihydrogen phosphate and copper acetate and mix them vigorously and then put in entered the mixing and grinding machine. The parts in the machine are thoroughly mixed together and ground. The solder paste is obtained in this way. The resulting solder paste shows a excellent stability in storage.

The soldering process is carried out in the same way as in Example 1, except that the flowability the ability to coat and the formation of defects in the pipe connection are checked.

The results that were obtained are of good quality for all points mentioned

Example 3
Prepare the solder paste

Ammonium dihydrogen phosphate
Copper formate

35 parts by weight
9 parts by weight

Octadecanamide

Solder powder (Sn50-Pb50,0,1 mm)

The preparation of the soldering paste and the implementation of the soldering process are carried out in the same way as in Example 1. The stability during storage, the flowability of the solder paste, the coating properties and the formation of imperfections in the pipe joint were checked. The related The results were satisfactory in all respects.

Example 4 Preparation of the solder paste

Phosphoric acid (85%) 39 parts by weight

Ammonium dihydrogen phosphate 39 parts by weight

Copper (II) oxalate 6 parts by weight

9-octadecanamide 6 parts by weight

Öiäthylenglycolmonobutyläther 10 parts by weight

Solder powder (Sn50-Pb50.0.1 mm) 100 parts by weight

6 parts by weight of the solder paste. In addition, the flux,

100 parts by weight applied during the soldering process

slightly carburized.

In this embodiment, Example 2 was repeated in the preparation, except that Diethylene glycol monobutyl ether was added to the phosphoric acid and then the amide was added. The soldering process is carried out in the same manner as in Example 1. The stability in the Storage, the flowability and the coating properties of the solder paste as well as the formation of defects examined. In this regard, satisfactory results were obtained on all points.

Example 5 Preparation of the solder paste

Phosphoric acid (85%) 26 parts by weight

Ammonium dihydrogen phosphate 40 parts by weight

copper (II) tartrate 6 parts by weight

Dodecanamide 3 parts by weight

piäthylenglycolmonoäthyläther 25 parts by weight

Solder powder (Sn50-Pb50.0.1 mm) 100 parts by weight

In this example, the preparation of Example 4 is repeated to produce the soldering paste. The soldering process is carried out as in Example I ₁ and the stability during storage, the flowability and the coating properties of the soldering paste and the formation of defects are checked. With regard to these points, the results were satisfactory

Comparative Example 1 Preparation of the solder paste

Phosphoric acid (85%) 65 parts by weight

Ammonium dihydrogen phosphate 20 parts by weight

Palm oil 15 parts by weight

Solder powder (Sn50-Pb50.0, 1 mm) 100 parts by weight

Predetermined amounts of phosphoric acid, ammonium dihydrogen phosphate and palm oil are used put into a mixing and grinding machine and intensively mixed and ground. A A certain amount of solder powder was added and the solder paste was obtained. The Lötvor

rd "as in example i comparative example 2 preparation of the soldering paste

Phosphoric acid (85%) 60 parts by weight

ίο arfimonium dihydrogen phosphate 23 parts by weight

Copper (II) formate 5 parts by weight of polyethylene glycol

(Molecular weight 1500) 12 parts by weight

Solder powder (Sn50-Pb50.0.1 mm) 100 parts by weight

In this example! Experimental example 1 is repeated to produce the solder paste. Of the Soldering is carried out in the same manner as in Embodiment 1. It was found that the Applying the solder paste to the surface of the stainless steel with the aid of a brush was difficult and that the flux applied to the surface during the soldering process slightly carburized, so that wetting of the surface of the stainless steel by the solder is insufficient Dimensions took place.

Comparative Example 3 jo Preparation of the solder paste

Phosphoric acid (85%) 60 parts by weight

Ammonium dihydrogen phosphate 23 parts by weight

K.upfer (II) formate 5 parts by weight

Lanolin 12 parts by weight

Solder powder (Sn50-Pb50,0.1 mm) 100 weight parts

Comparative Example 1 is repeated to prepare the soldering paste. The soldering process is the same Carried out as in embodiment 1. The application of the solder paste to the surface of the stainless steel is extremely difficult and the applied flux carburizes during the soldering process, so that sufficient wetting of the surface of the stainless steel is not possible

Comparative Example 4 Preparation of the solder paste

p gg p

1 carried out. The solder paste separated into the Solder and flux immediately after preparation

Phosphoric acid (85%) 78 parts by weight

Ammonium dihydrogen phosphate 10 parts by weight

Copper (II) formate 6 parts by weight

Octadecanamide 6 parts by weight

Solder powder (Sn50-Pb50.0.1 mm) 100 parts by weight

In this embodiment example 1 is repeated to prepare the soldering paste and example 1 is also repeated to carry out the soldering process. Pb50 had to be added in wire form into the gap of the connection point, shortly after the solder in the pasts had melted. In addition, a relatively highly qualified technique must be used in practice.

Comparative example! Prepare the solder paste

Ammofium dihydrogephosphate
K. copper (ll) formate
Octadecanamide

Diethylene glycol monobutyl ether
Solder powder (Sn50-Pb50,0,1 mm)

60 parts by weight
5 parts by weight
5 parts by weight

30 parts by weight
100 parts by weight

10

In this embodiment, diethylene glycol monobutyl ether is used instead of phosphoric acid. The soldering process is carried out as in Example I. The resulting solder paste shows none Adhesiveness, so that the application of the solder paste with the help of a brush on the surfaces to be connected is extremely difficult. In addition, the wetting process of the molten solder means a considerable one Loss of time. The molten solder tends to form pearls that fall off as drops. the Formation of numerous flaws was found

Comparative Example (US Pat. No. 3,963,162) Preparation of the solder paste

Phosphoric acid (85%) 25% by weight

Ammonium dihydrogen phosphate 70% by weight 72% by weight

CopperdD rormate 5% by weight

Ethylene glycol monoethyl ether 28% by weight

Solder powder (Sn 50-Pb 50, 0.1 mm)

50% by weight
50% by weight

The flux was placed in a mixer and grinder entered and mixed while stirring. The predetermined amount of solder powder was added to the mixing end Introduced grinding machine and mixed with sufficient agitation. This resulted in the Solder paste. The soldering process was carried out as in Example 1.

Immediately after the preparation of the soldering paste, the soldering paste had a good flowability and Soldering properties. One day after the preparation of the flux components, however, there was a separation and the solder paste had to be stirred again before use. One month after preparing the Solder paste had oxidized the solder and the solder paste was beginning to solidify.

π The results of the above examples are given in the following table:

Tabel

example Progressiveness Oiling process ! ■ "chlcrbcrcich
in the tube
link (%) Remarks example 1 Well Well 4-8 according to the invention
Paste for 2 weeks
shaped; no festivities
after a month Example 2 Well Well 4-8 the same Example 3 Well Well 4-8 the same Example 4 Well Well 4-8 the same Example 5 Well Well 4-8 the same Comparison
example 1 difficult with brush:
Brush slips upper
the surface Solder bead formation;
Carburized flux 25-30 **) after a day of tren
tion of the flux Comparison
example 2 difficult with brush the same 30-50 **) Comparison
example 3 difficult with brush the same 30-50 **) Comparison
example 4 Well low heat resistance
endurance; Solder only penetrates 10-20 pasty after
two weeks

difficult a

continuation 15th 28 21 538 16 • Remarks example Progressive Soldering process Error area
in the tube
link (%) Soot separates
after a day off;
Solidification after
one month Comparison
example 5
Comparison
example 6 difficult with brush
Well Solder bead formation
Well 20-30
4-8

Hints

1. Flowability of the solder paste:

The solder paste was checked to see if it was uniform and smooth on the surface with a painter's brush Coating can be applied.

2. Soldering process:

The solder paste was examined to determine whether the solder, when heated, the solder paste softly on the surface of the tube: stainless steel had been applied, turned silvery and whether a wire-shaped solder easily fell into the gap at the joint penetrates

3. The error range is given as a percentage in relation to the area of the joint of the pipes that are soldered together

The ratio of the defect area to the total area of the joint was mechanically broken by breaking the soldered Connection checked

**) The flaws or voids extend from one end to the other of the connection point. An error range of less than 20% is allowable from a practical point of view.

From the foregoing it can be seen that the invention shows a solder paste which is practical from the standpoint can be used to join stainless steel pipes together. The flux is on no corrosive phosphoric acid base built into which a soft solder is incorporated. The solder paste can be used with Use two-step soldering process in which an additional solder alloy in wire form is attached to the gap the connection point is introduced.

The solder paste obtained has good flowability and excellent stability during storage In this respect, the invention provides an improved soldering paste, which is particularly useful when connecting Stainless steel pipes can be used. Water or hot water can then flow through these pipes Water or another fluid medium can be passed through.

230 217/44!

Claims (3)

Patent claims: 1. Soldering paste for soldering items made of stainless steel, especially stainless steel pipes, with 20 to 80 wt .-% flux, which is phosphoric acid and ammonium dihydrogen phosphate contains, and 80 to 20% by weight of soldering powder distributed in the flux, characterized in that that, based on the total weight of the flux, the flux is 20 to 80% by weight Phosphoric acid (based on 85 to 86% by weight of orthophosphoric acid), 17.5 to 70% by weight of ammonium dihydrogen phosphate (NH4H2PO4), 0.5 to 10% by weight copper carboxylate and 2 to 15% by weight Contains carboxamide with at least 8 carbon atoms 2. Solder paste according to claim 1, characterized in that that the solder powder consists of a Sn-Pb solder 3. solder paste according to claim 1, characterized in that the flux also up to Contains 30% by weight glycol ether