DE2837616B1 - Heat exchanger for a fuel-heated heat source - Google Patents

Description

Claims: 1. Heat exchangers for fuel-heated heat sources, characterized in that it is with an alloy of tin 6-10%, antimony 4.5-6.5 %, The remainder lead and technical impurities is coated.

2. Heat exchanger for fuel-heated heat sources according to claim 1, characterized in that it is made with an alloy of 8% tin, 5.5% antimony, The rest of the lead and technical impurities are coated.

3. Method for leading a heat exchanger of a fuel-heated one Heat source using a metal alloy according to claims 1 or 2, characterized through the following steps: 1. Immersion in H3PO4 2. Immersion in HzO 3. Immersion in H2SO4 4. Immersion in H2O 5. Immersion in ZnCl2 6. Immersion in the lead bath according to claim 1 or 2 7. Dipping in H2O The present invention relates to a heat exchanger for a fuel-heated heat source.

Such heat exchangers are hitherto made of pure with a coating layer Lead has been provided. However, such a lead layer has proven to be relatively susceptible to corrosion proven.

Metal alloys with tin, antimony and lead are known. For example from DIN 1703, page 20, the white metal 5 and white metal 10 are tin-copper-antimony-lead alloys became known, the tin contents of which range from 4.5% to 5.5%, the copper content ranges from 0.5 to 1.5%, the antimony content from 14.5 to 16.5% and the rest is lead or

technically caused contamination.

A lead injection molding alloy has become known from DIN 1741, which contains a tin content of 6% and an antimony content of 9 to 11%, the rest is lead or technical impurities.

Furthermore, lead alloys are from DIN 16512 for the graphic industry become known, their tin contents of 2.5 to 3.5% with simultaneous antimony content from 3.5 to 4.5%, with the remainder being lead and technical impurities consists. Other alloys for printing purposes have significantly higher antimony contents or relatively high tin contents.

From leaflet »Steel«, No. 179, a lead bath alloy with up to 2.5% tin and 2% antimony have become known, which provide better adhesion of the lead layer should effect. At the same time, the extremely soft and easily damaged The pure lead layer is harder and more mechanically resistant due to the addition of antimony. The bath temperature can be increased by 40 to 50 ° by adding tin and antimony C to be lowered.

The present invention is based on the object of a heat exchanger to create, which is characterized by an extremely high corrosion resistance to exhaust gases, in particular exhaust gases containing sulfur dioxide, if the dew point is not reached excels.

According to the invention, the object is achieved with a heat exchanger of the type specified in the introduction in that it is made with an alloy known per se from 6 to 10% tin, 4.5 to 6.5% antimony, the remainder lead and technical impurities is covered. A coating alloy with a content of 8% tin, 5.5% antimony, the remainder lead and technical impurities.

It has been found that with these lead alloys a unexpectedly good corrosion resistance against humid exhaust gases containing sulfur dioxide results.

Known for heat sources heated by fuel for heat exchangers Leading alloys are essentially pure lead-tin alloys with a minimum of 6% tin, the remainder lead, up to higher tin contents.

The use of lead alloys containing antimony to keep copper heat exchangers was not obvious in the invention, because in one known case (2.5% Sn, maximum 2% Sb) the antimony to harden the lead layer serves and so that the lead layer is mechanically more resistant.

Both of these characteristics come into play when it comes to corrosion resistance not at all, as there is no mechanical effect on the lead layer takes place. The well-known antimony-lead alloys for printing purposes cannot either can easily be transferred to the invention, since it is the case with pressure metal alloys good corrosion resistance is not important, only easy castability and good impression.

Claims (1)

The method according to the invention for leading a heat exchanger a fuel-heated heat source assumes that the sheet copper (99.9% Cu, 0.015-0.050% P, the remainder technical impurities, d. H. SF-Cu) existing Heat exchanger in the form of a heating shaft with an internal lamellar block which a copper water pipe is led, first immersed in phosphoric acid, then rinsed in water and then immersed in sulfuric acid, whereupon a Rinsing takes place in water, which is followed by immersion in the flux (ZnCl2 in aqueous Solution). Next comes the immersion in the lead soon, consisting of made of a lead alloy with 8% tin, 5.5% antimony, the remainder lead and technically required Impurities. To remove the salt residues, it must then be immersed in water will. Alternatively, after the lead has been passed, the part can be placed in a 5% aqueous HCl solution dipped and then rinsed with water.