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FETS – RFQ Cold Model Vacuum Braze By P. Savage 1 st May 2007

FETS – RFQ Cold Model Vacuum Braze By P. Savage 1 st May 2007. Braze Test. Braze Test. Braze Test. Groove on one half only, 2mm wide max x 2mm deep. Stop groove short of ends. Ask for barrier stuff on inside faces. Area reducing recess – one side only.

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FETS – RFQ Cold Model Vacuum Braze By P. Savage 1 st May 2007

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  1. FETS – RFQ Cold Model Vacuum Braze By P. Savage 1st May 2007

  2. Braze Test

  3. Braze Test

  4. Braze Test

  5. Groove on one half only, 2mm wide max x 2mm deep. Stop groove short of ends. Ask for barrier stuff on inside faces. Area reducing recess – one side only. No need for support structure or clamps to retain KFs. They will do. No overall clamping structure required. Ask about two types of braze material. (One needs KFs to be plated) Get electrical conductivity of each. Did we order C101? Zirconium oxide – braze material? Give one weeks notice. Arrange for braze on a Monday – they will bake out ovens over weekend. Can take pictures and measure before goes in oven. Braze will take about 5 hrs, @1000C, @5x10-4 Provide measurement holes.

  6. Brazing slots to be facing downward when job assembled to improve flow • Green stop-off pen used on inner faces to prevent over-flow • KF’s can be tighter • KF holes ideally to have braze groove around the inside or at the bottom of the hole (approx 1mm wide x 1mm deep). And/or 1mm chamfer at top of braze hole. • Measurement impossible due to braze material lifting piece. • Thermocouple holes – 1.7 – 1.8mm diameter x 5dp at the middle and end so that we can see the temperature of the braze interface. • We actually had 8hrs at 935C, then fast cooled. NB: Had 2 goes to melt braze material.

  7. RFQ assembled without brazing _____________________________________________________________________ The photo shows the assembled RFQ structure sitting in it’s mounting frame.

  8. RFQ quarters Braze faces with 2mm wide slots for the braze material ____________________________________________________________________________________ The photo shows two of the small quarters either side of one of the two large quarters that together make up the full RFQ. The braze faces with slots to accept the braze paste are indicated.

  9. First braze pass _____________________________________________________________________________ For the first braze pass the separate quarters are laid out with their KF40 flanges in place.

  10. Second braze pass _________________________________________________________________ For the second braze pass the quarters are assembled and brazed together.

  11. Melting points of metals ______________________________________________ Source: http://www.muggyweld.com/melting.html

  12. TECVAC

  13. TWI Knowledge Summary Furnace brazing by Sue Dunkerton The process - Brazing is the process of joining metallic or ceramic materials using a molten filler metal, drawn into the joint by capillary action or preplaced with preform. Usually, filler metal becomes molten well below the melting point of the materials being joined, although in some cases, the melting points are close but again the filler is the lower melting point material. Various methods are used to braze components, and this summary provides background on the use of furnace brazing. Furnace types - The popularity of furnace brazing stems from the clean atmosphere used, which mostly eliminates use of fluxes and also eliminates post-braze cleaning. Various types of furnace are used for brazing, mostly employing either a gaseous atmosphere or vacuum. The overall furnace construction is based on either batch type or continuous operation. Batch operation includes retort type furnaces used for hydrogen brazing, and vacuum chambers for vacuum brazing. In a retort furnace, an inner heat resistant alloy container retains and protects the enclosed hydrogen atmosphere. Hydrogen provides the active ingredient to clean the braze components, and eliminates the need to use flux. To speed up brazing cycles, these furnaces would typically use a nitrogen purge at the end of the cycle to accelerate cooling rates. Although care needs to be taken with potentially explosive mixtures of hydrogen and air, equipment is designed and safeguarded to prevent this. Alternatively, lower percentages of hydrogen are used by using mixed gases based on hydrogen with nitrogen, argon or helium. Vacuum furnaces are widely used, and often companies will utilise them for heat treatment as well as brazing, dependent on capacity. Furnaces today are based on a cold wall construction, with internal heating elements, usually carbon or molybdenum. The cold wall refers to the water cooled doubled skin construction, to keep external temperatures down to room temperature (or less). Either horizontal furnaces with side loading are used or vertical furnaces loaded from the top or bottom. Furnace temperatures up to 1650°C are readily available. Vacuum furnaces are high capital investments, but they are versatile, safe and produce a high quality product. Materials - Most materials can be furnace brazed, although high vapour pressure elements should be avoided in vacuum brazing (zinc, cadmium, lead, etc). All materials need to be cleaned prior to insertion in the furnace to remove surface scale, grease and other contaminants (high quality in, high quality out). The most widely used fillers for furnace brazing are based on silver, copper, nickel and gold, the latter two being most applicable to stainless steels, and heat and corrosion resistant alloys. Applications - Furnace brazing is more applicable to value added components because of the high capital outlay and less productive duty cycles compared with other 'lower cost' brazing alternatives. However, applications still include high volume components for the electrical and electronic sectors. Other large markets include aeroengine components, power generation components (nuclear and gas turbine) and various marine and other engineering applications. The last decade has seen increasing vacuum brazing of aluminium heat exchangers because of the clean processing possible, and the advent of large brazing furnaces (greater than 2x1m). Benefits - Furnace brazing has the key advantages of a controlled heating cycle, and that clean parts may be processed with no need for post-braze cleaning. Precautions - There are no significant risks associated with vacuum brazing other than the normal for such equipment (electrical, thermal). If volatile materials should be placed in the furnace, extraction should be examined to ensure venting into a safe area. In furnace brazing, there may be specific precautions to take where a hydrogen atmosphere is used.

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