DE2833840A1 - METHOD FOR COATING AND SOLDERING WORKPIECES WITH CARBIDE ALLOYS - Google Patents

Description

Metallgesellschaft AG July 27, 1978

Reuterweg 14 DRLA / CPA 6000 Frankfurt / Main

No. 8248 LT

Process for coating and soldering workpieces with Carbide alloys

The invention relates to a method for coating and soldering Workpieces with hard metal alloys, mixtures of hard metal alloys with hard materials or soft or hard soldering in forms, by applying these alloys or mixtures in powder or form granular form, if necessary with the addition of binders, such as plastics, on the workpieces to be coated in the respective desired Layer thickness, adjustment of this layer thickness, if necessary by means of spacers and subsequent heat treatment of the whole.

It is known to produce sharp edges when armoring To process machine parts and workpieces with hard metal alloys or mixtures of hard metal alloys with hard materials in such a way that one around the workpieces to be armored in one of the respective Armor chxchtdicke corresponding distance puts a mold made of inorganic material or metal around into the The cavity formed between the workpiece and the mold gives up the mass intended for armouring and

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protection gas sinters. After the sintering process, the shape surrounding the workpieces can then be completely or partially ground away (DT-OS 19 21 568).

With this method it is possible to produce sharp contours and edges on workpieces of all kinds in the desired thickness. In some Cases it turns out, however, that after this or after other known The hard material or carbide distribution in the finished coating is not optimal i.e. that the specifically heavier hard materials or carbides sink downwards according to the force of gravity. That means, that a depletion of these hard materials or carbides occurs in the upper part of the armor, while in the lower part of the Armor enrichment takes place. This has the consequence that the wear resistance of the armor only after a certain Loss of volume of the coating is optimal. This reduces the efficiency of the armor and its economic viability reduced.

The invention is based on these and other disadvantages of the prior art and to propose a method that allows a high hard material or carbide concentration to effect on the upper, first exposed to wear part of the armor layer. The utility value and the service life the armor should be increased and the coating material used can be used to the full.

The process should be economical and flawless in a short time Enable coatings.

This object is achieved according to inven tion by the fact that in the shape of the powder or granular coating material

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brings, inserts the workpiece to be coated and optionally heated under pressure.

In the context of the invention, self-fluxing hard metal alloys are preferred as powder or granular coating material based on Ni or Cu, mixed with B, Si and / or P used.

To the same extent can be used as a powder or granular coating material Mixtures of hard metal alloys with hard materials can also be used.

Hard materials within the scope of the invention are e.g. carbides, such as WC, Borides and nitrides. Minerals such as quartz, corundum and diamond are also suitable as hard materials. Also covered with metals Hard materials can be used as well as mixtures of different hard materials.

According to a further development of the invention, soft or hard solders are based on powder or granular coating material Cu, Ag, Cd and / or Pb are used.

One embodiment of the invention is that after the ' Introducing the powder or granular coating material introduces a layer of stress relieving material.

As the stress relieving material, powder or granular coating material having lower hardness than the first can be used Powders or granular coating material introduced into the mold can be used.

The whole can be heated in an oven. It can also be done inductively or it can be used

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for this a salt bath. Furthermore, the heating can be carried out under an inert atmosphere.

According to the invention, the coating of the workpiece can also be carried out under pressure.

The advantages achieved by the invention are in particular that it is a simple and economical process succeeds in providing workpieces with a firmly adhering layer of hard metal.

By means of constructive measures, as known from soldering technology, it is possible according to this method during the actual Coating process to solder dissimilar materials, for example hard metals to a carrier. This possibility is then of importance when different stresses on the workpiece require the use of different materials make chemical and physical properties necessary.

The coating immediately develops its wear-resistant properties and does not need to be worn down to a certain extent. This significantly increases the durability of the applied layers. The proposed method is very versatile. The weight of the coating material of the so-called carrier presses into the melt during the coating process and solidifies these. Due to the weight of the girder or an additional load, liquid metal is also pressed into narrow gaps or drawn in by capillary action. This process, which corresponds to a soldering process, is not only possible horizontally to coat horizontal surfaces, but also vertical surfaces and surfaces shaped in various other ways. Further by flowing around the liquid alloy, it can also be used on all sides

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Coating of workpieces can be effected. Another advantage is that there are no after-run problems of the powder. In many known methods, for example, the liquid alloy does not flow or flows only imperfectly on the walls of the mold away. The result is that not only valuable coating material is lost, but also the mold must be cleaned or freed from adhering powder after each coating process, which is associated with considerable expenditure of time. The surface of the armor layer is homogeneous and smooth.

The invention is exemplified and schematic in the drawings and is described in more detail below.

Show it:

1 shows the coating of valve seat rings

a) Before coating

b) after coating

2 shows the coating of valve seats

a) before coating

b) after coating

3 shows the coating of baffle plates

a) before coating

b) after coating

4 shows the coating and soldering of a workpiece

a) before coating

b) after coating

In the figures:

a) Before coating

1 the shape, 2 the workpiece to be coated, 3 the

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brought powder or granular coating material, 4 the spacer, 5 another layer of powder or granular coating material, 6 the core, 7 the workpiece to be soldered on and 8 the Guide or bracket

b) After coating

1 'the shape, 2' the coated workpiece, ^3J the applied layer, ^4J the spacer, 5 'another applied layer, 6' the core, 7 'the workpiece that is soldered on and 8' the guide or holder.

example 1

According to FIG. 1, a hard metal alloy powder is placed in the mold 1 made of CrNiBSi with a fraction of 30 to 100 μm filled in loosely. The loosely introduced powder is pre-compacted by vibration and leveled in the process. Then the cleaned, from dust and dirt freed valve seat ring is placed as workpiece 2 to be coated. Form 1 and workpiece 2 are put together in a vacuum oven 11/2 hours at a temperature of 1050 C in a vacuum

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heated from 10 to 10 torr. It is then cooled in the oven and the coated workpiece is removed from the mold.

Example 2

According to Fig. 2, the coating of valve cones is carried out, as they often occur in the valve industry.

The coating material 3 is a Co-Cr-W-B hard alloy in form 1 made of porcelain with a dimensionally accurate and particularly smooth inner surface Filled with approx. 40 HRc in an exactly precalculated weight proportion without pre-compression. Workpiece 2 is placed on a powder surface 3 and fixed by a guide 8 so that vertical immersion in the melt is guaranteed.

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is guaranteed. At the same time, this leadership takes over the function of the spacer in that they are immersion only up to a pre-calculated depth. Through inductive heating The powder is melted in an inert atmosphere. According to the surface smoothness and the dimensional accuracy the form a tightly toleranced coating is achieved, so that only a very fine machining is required to achieve the tightest Tolerances and maximum surface smoothness is required.

Example 3

According to FIG. 3, impact or wear plates are to be produced. Wear plates for bunker walls are usually made of a wear-resistant and thus brittle cast. Often> times Even tightening the fastening screws leads to stress cracks and thus to breakage of the panels. This effect is still in the installed state due to relatively low impact loads achieved.

The highly wear-resistant hard alloy in powder form 3, consisting of a mixture with 50% by weight each, is first put into form 1 Ni-Cr-BrSi with approx. 60 HRc and tungsten carbides introduced and leveled. A stress-relieving Ni-Cr-B-Si alloy with 30 - 35 HRc 5 is also abandoned as the second alloy. On this Depot, the carrier 2 is placed on the inside with spacer 4, consisting of Ni-Cr-B-Si bright bars and a sand cast core became. The fusion bonding was carried out according to Example 1.

According to the method according to the invention, the clamping forces on the tough Transfer carrier. In order to increase the impact stress, a double or triple fill of alloys is placed underneath.

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different chemical composition and hardness. In this way, high tensions are relieved, which is the case with stronger Impact, impact or pressure on the brittle wear layer act.

Example 4

According to FIG. 4, a carrier is used as the workpiece 2 to be coated made of St 37 together with a tube 7 made of austenitic material 1.4571 on the powder depot 3, consisting of a Ni-Cr-B-Si alloy put on with 60 HRc. The tube 7 is pressed down to the bottom of the mold. To an alloying to accumulated inside the tube To prevent powder, it is sucked off before it is placed in the oven.

The system is then heated in a vacuum oven above the melting point of the powder. The carrier 2 sinks down to the one on the pipe 7 attached stop. The melt is alloyed to the carrier 2 by diffusion. The soldering gap between carrier 2 and tube 7 becomes filled with the coating material 3 and there is a solid connection.

Patent claims

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Claims (11)

Claims 1. Process for coating and soldering workpieces with hard metal alloys, mixtures of hard metal alloys with hard materials or soft or hard solders in molds, by applying these alloys or mixtures in powder or granular form, possibly with the addition of Binders such as plastics, on the workpieces to be coated in the respective desired layer thickness, adjustment of this layer thickness, if necessary by spacers and subsequent heat treatment of the whole, characterized in that the powder or granular coating material is introduced into the mold, the workpiece to be coated is inserted and optionally heated under pressure. 2. The method according to claim 1, characterized in that self-flowing hard metal alloys based on Ni or Cu, mixed with B, Si and / or P, are used as powder or granular coating material. 3. The method according to claim 1 and 2, characterized in that mixtures of hard metal alloys with hard materials are used as powder or granular coating material. 4. The method according to one or more of the preceding claims 1-3, characterized in that soft or hard solders based on Cu, Ag, Cd and / or Pb are used as powder or granular coating material. 5. The method according to one or more of the preceding claims 1-4 , characterized in that after the introduction of the powder or granular coating material, a layer of a stress-reducing material is introduced. 030008/0087 * - ORIGINAL [NSPECTK) 6. The method according to one or more of the preceding claims 1-5, characterized in that a powder or granular coating material with a lower hardness than the powder or granular coating material first introduced into the mold is used as the voltage-reducing material. 7. The method according to one or more of the preceding claims 1-6, characterized in that the heating is carried out in the oven. 8. The method according to one or more of the preceding claims 1-7, characterized in that the heating is carried out inductively. 9. The method according to one or more of the preceding claims 1-8, characterized in that the heating is carried out in a salt bath. 10. The method according to one or more of the preceding claims 1 to 9, characterized in that the heating is carried out under an inert atmosphere. 11. The method according to one or more of the preceding claims 1 to 10, characterized in that the coating is carried out under pressure. 030008/0087