8. Resistance Spot Welding, Resistance Projection Welding and Resistance Seam Welding
8. Resistance Spot-, Resistance Projection- and Resistance Seam Welding 05 Figure 8. shows an extract from the classification of the methods according to DIN 90 with a detailed account of the conductive resistance pressure. In the case of resistance pressure, the heating occurs at the point as a consequence of Joule resistance heating caused by current flow through an electrical conductor, resistance spot br-er8-0e.cdr Figure 8. spot cold pressure induction pressure workpieces overlap electrode weld nugget electrode force elektrodes 3 production part br-er8-0e.cdr Figure 8. 3 pressure projection resistance pressure Conduction pressure roller seam Classification of Welding According to DIN 90 roller seam workpiece usually in general overlap driven roller electrode spot rows (stitch weld, roller spots) 4 loaded area 4 3 fusion resistance butt friction flash butt projection workpieces with elevations (concentration of electicity) workpieces overlap pad electrode several joints in a single weld weld nugget joint 5 projection 3 5 Figure 8.. In spot and projection, the plates to be welded in overlap. Current supply is carried out through spherical or flat electrodes, respectively. In roller seam, two driven roller electrodes are applied. The plates to be welded are mainly overlapped. The heat input rate Q input is generated by resistance heating in a currentcarrying conductor, Figure 8.3. However, only the effective heat quantity Q eff is instrumental in the formation of the weld nugget. Q eff is composed of the input heat minus the dissipation heat. The heat loss arises from the heat dissipation into the electrodes and the plates and also from thermal radiation.
8. Resistance Spot-, Resistance Projection- and Resistance Seam Welding 06 The resistance during resistance heating is composed of the contact resistances on the two plates and of their material resistance. The reduction of the electrode force down to 90% increases the heat input rate by 05%, the reduction of the current down to 90% decreases the heat rate to 80% and a time reduction to 90% decreases the heat rate to 9%. The time progression of the resistance is shown in Figure 8.4. The contact resistance is composed of the interface resistances between the electrode and the plate (electrode/plate) and between the plates (plate/plate). The resistance height is greatly dependent on the applied electrode force. The higher this force is set, the larger are the conductive crosssections at the contact points and smaller the resistances. The contact surfaces, which are rapidly increasing at the start of, effect a rapid reduction of interface resistances. With the formation of the weld nugget the interface resistances between the plates disappear. During the progress of the weld the material resistance increases from a low value (surrounding temperatures) to a maximum value above the melting temperature. mohm resistance F el: electrode force Q eff: effective heat Q input: total heat input I: current (time dependence) Q : heat losses Q : losses into the electrodes Q 3: losses into the sheet metal Q 4: losses by heat radiation R(t): total resistance R material(t): material resistance R c(t): contact resistance br-er8-03e.cdr Q = Q br-er8-04e.cdr Figure 8.4 - Q eff input l Q = Q + Q 3 + Q4 R(t) = R Figure 8.3 t=t S Q input = C I (t) R(t) dt t=0 material (t) + R (t) total resistance sum of material resistance sum of contact resistances 5 0 periods time c Q 3 Q 4 Q 4 Q eff F el Q Q F el Heat Balance in Spot Welding Q 4 Q 4 Q3 theoretical contact area 00% metallic conduction contact proportion at room temperature low electrode force high resistance high electrode force low resistance proportion after first milliseconds time surface resistance is collapsed, a 3 is highly extended A: area out-of-contact A: contact area with high resistance A3: contact area completely conductive
8. Resistance Spot-, Resistance Projection- and Resistance Seam Welding 07 Figure 8.5 shows diagrammatically the different electrode force resistance rate resistances during the spot R R3 process with acting electrode force, but without current. Weld nugget formation must therefore start in the joining zone because of ~_ R 5 R 3 R 6 R 7 R 4 R R6 R5 R7 R4 0 00 00 R [µohm] the existing high contact resistance there. br-er8-05e.cdr Figure 8.6 shows directly Figure 8.5 cooled electrodes for resistance. The coolant cooling tube is normally water. In the cooling tube, the cooling 6-8 cooling drill-hole slope water is transported to the 0-0 -5 electrode base. The diagram shows the temperature distribution in the electrodes and in the plates. C The maximum temperature is reached in the centre of the weld nugget and de- br-er8-06e.cdr Electrode Cooling creases strongly in the electrode direction. Figure 8.6 Sequence of a resistance spot process, Figure 8.7: -> Lowering of the top electrode ->3 Application of the adjusted electrode force Set-up time t pre, sequence 3->4 Switching-on of the adjusted current for the period of the time t w. Formation of the weld nugget in the joining zone of both workpieces.
8. Resistance Spot-, Resistance Projection- and Resistance Seam Welding 08 An example shows the macrosection of a weld nugget after the time has ended. 4->5 Maintaining the electrode force for the period of the set post-weld holding time t h. 5->6 Switching-off the force generating system and lifting the electrodes off the workpiece. The functions of the set-up time and the post-weld holding time are listed in Figure 8.8. Dependent on the task different force and current programs can be set in the machines, Figure 8.9. In the top the simplest possible program sequence is shown: The application of the electrode force, the set-up time sequence t pre, the switching-on of the current and the sequence of the time t w, the sequence of the postweld holding time t h and the switching-off of the force generating system. The diagram in the centre is almost identical to the one just described. Merely in the current range, is carried out using an adjustable current rise (7) and current decay (8). The diagram below depicts a more sophisticated current program. In addition, is carried out with a variable electrode force () and with preheating (4) and post-heating current (6). Dependent on the control system, the process can be influenced by adjustment. F el I w electrode force F el current I w t pre t w t h time t set-up time - compressing the workpiece - build-up of electrode force to preset value - setting-up of reproducible resistance before - electrode resting after bounce - preventing resting of electrode on workpiece under electricle voltage top electrode postweld-holding time workpiece lower electrode weld nugget - holding time of workpiece during cooling of molten metal - prevention of pore formation in the nugget - prevention of lifting the electrode under voltage insufficiently melted weld nugget totally melted weld nugget The postweld-holding time has influence on the weld point hardening within certain limits. br-er8-07e.cdr br-er8-08e.cdr Time Sequence of Resistance Spot Welding Functions of Pre- and Post Figure 8.7 Figure 8.8
8. Resistance Spot-, Resistance Projection- and Resistance Seam Welding 09 A controlled variable may be, for instance, the electrode path, the resistance progress, the current or the voltage. Figure 8.0 shows the principle structure of a resistance spot machine. The main components are: the machine frame, the transformer with secondary lines, the electrode pressure system and the control system. This principle design applies to spot, projection and roller seam machines. Differences are to be found merely in the type of electrode fittings and in the electrode shapes. electrode force current 5 I w F el t pre = pre-weld time t w = time t h = holding time t = pressure time pres 9 t pre t w t h t pres time 0 electrode force current 5 I w 7 8 F el 6 7 4 3 5 time 8 electrode force current 5 I w 4 6 7 8 3 br-er8-09e.cdr ISF 006 F el - initial force - pressure force 3 - post pressure force 4 - preheating current 5 - current 6 - postheating current 7 - ascending current 8 - descending current time br-er8-0e.cdr electrode force cylinder pneumatic equipment 3 machine tool frame 4 transformer 5 power control unit 6 current conductor 7 lower arm 8 foot switch 9 top arm 0 electrical power supply cable water cooled electrode holder electrode Course of Force and Current Schematic Assembly of Spot Welding Machine Figure 8.9 Figure 8.0 Figure 8. depicts the possible process variations of resistance spot. These are distinguished by the number of plates to be welded and by the arrangement of the electrodes or, respectively, of the transformers. It has to be noted that with a corresponding arrangement also plates can be welded where one of the two plates has a non-conductive surface (as, for example, plastics).
8. Resistance Spot-, Resistance Projection- and Resistance Seam Welding 0 Figure 8. shows the current types which are normally used for resistance. Alternating current has the simplest structure (Figure 8.3) and is most price effective, unavoidable are, however, the disadvantages of current zeros and weld nugget cooling. In relation to the average current values, peak loads occur and, with that, increased electrode wear. These extreme peak loads do not occur with direct current. two-sided single-shear single-spot + two-sided duplex spot br-er8-e.cdr Figur 8. ~ ~ + ~ two-sided two-shear spot (stack ) + ~ one-sided duplex spot with conductive base Variants of Spot Welding ~ one-sided single-spot with contact electrode + + ~ one-sided multi-spot with conductive base ~ The structural design of a d.c. supply unit is, however, more complicated and, therefore, more expensive than an a.c. supply unit. As conventional machines operate with a 50 Hz primary current supply, the current can be controlled only in 0 ms units ( period). When the inverter-direct current current [ka] current [ka] 0 5 0 5 br-er8-e.cdr Figur 8. alternating current 0 0.00 0.0-5 0.04 0.07 0.09 0. 0.3 0.6-0 -5-0 8 6 4 0 8 6 time [s] "conventional" direct current 4 0 0.00 0.0 0.04 0.06 0.08 0.0 0. 0.4 0.6 current [ka] current [ka] 0 45 40 35 30 5 0 5 0 5 0 Current Types 8 6 4 0 medium frequency direct current 0.00 0.0 0.04 0.06 0.08 0.0 0. 0.4 0.6 time [s] impulse capacitor current 0.00 0.0 0.04 0.06 0.08 0.0 0. 0.4 0.6 time [s] time [s] technique or, respectively, the medium-frequency technique is used, a finer setting of the current-on period and a more precise control of the current is possible. In order to realise higher currents and shorter times, the impulse capacitor resistance technique is applied. The rectified primary current is stored in capacitors and, through a high-voltage transformer, converted to
8. Resistance Spot-, Resistance Projection- and Resistance Seam Welding high currents. The advantages of this technique are low heat input and high reproducibility. Because of the high energy density, materials with good conductivity can be welded and also multipleprojection welds can be carried out. A disadvantage of this method is, apart from the high equipment costs, the difficult regulation of the current. br-er8-3e.cdr Figure 8.3 single-phase alternating current 3-phase direct current static-inverter direct current capacitor impulse discharge Electrodes for spot resistance have the property of transferring the electrode force and the current. They are wearing parts and, therefore, easily replaceable. requirements form A form B electrodes form C form D - good electrical conductivity - good thermal conductivity - high high-temperature strength - high temperature stability - high softening temperature - little tendency to alloying with workpiece material - easy options in machining form E form F form G ISO 58 Group Type No. Key ISO 58 Group Type No. Key electrode caps A 3 4 3 4 Cu - ETP Cu Cdl Cu Crl Cu Crl Zr Cu CO Be Cu Ni Si Cu Ni P Cu Be Co Ni Cu Ag6 CuAl0NiFe5Ni5 B 0 3 4 5 W75 Cu W78 Cu WC70 Cu Mo W W65 Ag electrode holders br-er8-4e.cdr br-er8-5e.cdr Electrodes, Electrode Caps and Holders Electrode Materials Figure 8.4 Figure 8.5
8. Resistance Spot-, Resistance Projection- and Resistance Seam Welding Depending on the shape and type of electrode, solid electrodes or electrode caps, must be either remachined or recycled. Figure 8.4 depicts various types of electrodes, electrode caps and holders. Dependent upon the electrode application, different alloyed electrode materials are used, Figure 8.5. The added alloying elements influence the red hardness, the tempering resistance, the conductivity, the fusion temperature, the electrode alloying tendency, and, finally, the machinability of the electrode material. When beryllium is used as an alloying element, the admissible MAC values must be strictly adhered to during remachining or dressing of the electrodes. Already during the design phase of the components to be welded, importance must be attached to a good accessibility of the point. Moreover, the electrode force which is imperative to the process must be applied in a way that no damage is done to the workpiece. In the ideal case, the point is accessible from the top and from below, Figure 8.6. poor good poor good br-er8-6e.cdr br-er8-7e.cdr Accessibility for Spot Welding Electrode Contact Area for Spot Welding Electrodes Figure 8.6 Figure 8.7
8. Resistance Spot-, Resistance Projection- and Resistance Seam Welding 3 In order to avoid the displacement of the electrodes, the electrode working surface must be flat. Also during the design phase space must be provided for an adequately large spot A clearing zone around the working point, in order to guarantee the unimpeded electrode shunt connection current approach to the working point, Figure 8.7. Dependent on the joining job, the process current path indirect one side copper variation, or the resistance method, a so-called shunt current/effect may be noticed. This current component, as a rule, does not contribute to the formation of the weld nugget; under certain circumstances it might br-er8-8e.cdr roller seam even prevent a reliable process. In Shunting the example, shown in Figure 8.8, the shunt Figure 8.8 current leads to undesired fusing contacts and, because of the lacking electrode force at this point, also to damages to the plate surface. Welding spatter: Discharge of molten material between two steel sheets or from the surface of steel sheets. If unsuitable parameters have been set, weld spatter formation may occur, Figure 8.9. Liquid molten metal forms on the plate surface or in the joining zone. The reasons for this kind of process disturbance are, for example, too low an electrode force with regard to the set current or time, too high an energy input with regard to the plate thickness or too small an edge distance of the point. br-er8-9e.cdr fig. fig. Reason here is high current, (fig. ) or too-small edge distance (fig. ) porosity in the joint caused by spatter Welding Spatter discharge of molten material at the joint plane Figure 8.9
8. Resistance Spot-, Resistance Projection- and Resistance Seam Welding 4 Figure 8.0 shows a list of alteration to force alteration of pressure plate shunt connection wear of electrodes Q = Q - Q eff input losses current changes wear of cable Q eff mains voltage fluctuation secondary electrical impedance wear diversion heat equipment a large number of possible disturbances in resistance spot. Welding current changes are caused by: shunt, electrode wear, cable wear, mains voltage plate thickness quality of plates number of plates plate surface edge distance variations, secondary impedance. modification of the unit br-er8-0e.cdr Different conditions are caused by machine wear, different Figure 8.0 heat dissipation. Nonuniform conditions by alterations to components are: different plate thicknesses, plate quality, number of plates, plate surfaces, edge distances. Electrode force changes are caused by: pressure fluctuations and -changes, plate bouncing. The resistance spot method allows of a large number of materials. A list of the various materials is shown in Figure 8.. The alloying elements which are used for steels have a varying influence on the suitability for resistance spot. The values which are indicated in the table are valid only when the stated element is the sole alloying constituent of the steel material. Figure 8. shows a comparison between resistance spot and resistance projection. The fundamental difference between the two methods lies in the definition of the current transition point. materials aluminium iron gold cobalt copper magnesium weldable materials br-er8-e.cdr weldability molybdenum satisfactory nickel platinum silver tantalum titanium tungsten satisfactory very good satisfactory very good poor good very good very good very good very good very good satisfactory C alloying elements C + Cr C + Mo C + V C + Mn C + Ni Si Cu P + S C+Cr+Mo+V good weldability Weldable Materials sufficient weldability maximum content [%] 0,5 0,35 0,50 0,40,40 3,00 0,40 0,60 0,0 0,60 influence of alloying elements (steel materials) 0,40,60 0,70 0,60,60 4,00,00 0,60 0,0,60 Figure 8.
8. Resistance Spot-, Resistance Projection- and Resistance Seam Welding 5 The differences between both methods are illustrated in Figure 8.3. The short life of the electrodes used for resistance spot is explained by the higher thermal load and the larger pressing area caused by the smaller electrode contact areas. The term electrode life stands for the number of welds that can be carried out with one pair of electrodes without further rework and without exceeding the tolerances for quality criteria of the weld. before after Depending on the demands on the joint strength follow-up distance or on the projection rigidity, different projection shapes elektrode are applied. These are an- projection nular, circular or longitudi- br-er8-e.cdr nal projections. The projections are, accord- Figure 8. spot projection embossed projection shape solid projection shape natural projection shape elektrodes: diameter tip face electrode life up to 0 mm convex less > 0 mm flat longer pressed mould pressed struck machined cut pushed place where the nugget originates elektrodes projections circular longitudinal annular circular longitudinal annular interrupted annular spot contact line contact number of nuggets one several follow-up distance small big Circular weld nut crossed wires problems: Longitudinal cut wire-plate current distribution no yes force distribution no yes Annular pushed bolt-pipe br-er8-3e.cdr br-er8-4e.cdr Differences Between Resistance Spot and Projection Welding Customary Projection Shapes Figure 8.3 Figure 8.4
8. Resistance Spot-, Resistance Projection- and Resistance Seam Welding 6 ing to their size, adapted to the used plate plate die plate die thickness and may, therefore, appear as different types in the workpiece: embossed projections, solid projections and natural projections. The survey is shown in Figure 8.4. br-er8-5e.cdr d mould plate embossed projection Figure 8.5 l mould plate counter-die die mould plate longitudinal projection d ring projection Production of Embossed Projection Shapes b plate In Figure 8.5 the production of embossed projections in different shapes is shown. The shape is embossed onto the plate surface by appropriate die plates, dies and, if necessary, counter dies. Various problems occur in projection caused by the of several joints in a single working cycle. Due to different current paths - when using direct current - and a current displacement - when using alternating current -, nuggets with differing quali- alternating current distribution intensity of current increases from the center to the outer area caused by current displacement force distribution of a C-frame projection press welder during bending of machine tool frame direct current distribution intensity of current decreases from the center to the outer area caused by the longer current path force distribution of a C-frame projection press welder with non-parallel positioning tables br-er8-6e.cdr br-er8-7e.cdr Problem of Current Distribution During Projection Welding Problems of Force Distribution During Projection Welding Figure 8.6 Figure 8.7
8. Resistance Spot-, Resistance Projection- and Resistance Seam Welding 7 ties are produced when no preventive remedies are taken, Figure 8.6. A varying force distribution, as shown by the example in Figure 8.7, also leads to differing qualities of the produced weld nuggets. br-er8-30e_sw.cdr Figure 8.8 Application Examples of Projection Welding In Figure 8.8 several examples of application using projection are depicted. In this example, the shapes are of the embossed type. Figures 8.9 and 8.30 show several process variations of roller seam. Seam is actually a continuous spot process, but with the application of roller electrodes. In contrast to resistance spot the electrodes remain in contact and turn continuously before after br-er8-8e.cdr lap joint lap joint with wire electrode lap joint with foil Roller Seam Welding squash seam weld butt weld with foil after the first weld spot has been produced. At the points where a spot is to be produced again current flow is initiated. Dependent on the electrode feed rate and on the current frequency, spot welds or seal welds with overlapping weld nuggets are produced. The application of d.c. current also produces seal welds. Figure 8.9
8. Resistance Spot-, Resistance Projection- and Resistance Seam Welding 8 interrupted-current roller seam weld overlap seal weld continuous D.C. seal weld br-er8-9e.cdr Weld Types for Roller Seam Welding Figure 8.30