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Electric resistance welding
Electric resistance welding
Electric resistance welding
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Electric resistance welding (ERW) is a welding process in which metal parts in contact are permanently joined by heating them with an electric current, melting the metal at the joint.[1] Electric resistance welding is widely used, for example, in manufacture of steel pipe and in assembly of bodies for automobiles.[2] The electric current can be supplied to electrodes that also apply clamping pressure, or may be induced by an external magnetic field. The electric resistance welding process can be further classified by the geometry of the weld and the method of applying pressure to the joint: spot welding, seam welding, flash welding, projection welding, for example. Some factors influencing heat or welding temperatures are the proportions of the workpieces, the metal coating or the lack of coating, the electrode materials, electrode geometry, electrode pressing force, electric current and length of welding time. Small pools of molten metal are formed at the point of most electrical resistance (the connecting or "faying" surfaces) as an electric current (100–100,000 A) is passed through the metal. In general, resistance welding methods are efficient and cause little pollution, but their applications are limited to relatively thin materials.

Spot welding

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Spot welder
Main article: Spot welding

Spot welding is a resistance welding method used to join two or more overlapping metal sheets, studs, projections, electrical wiring hangers, some heat exchanger fins, and some tubing. Usually power sources and welding equipment are sized to the specific thickness and material being welded together. The thickness is limited by the output of the welding power source and thus the equipment range due to the current required for each application. Care is taken to eliminate contaminants between the faying surfaces. Usually, two copper electrodes are simultaneously used to clamp the metal sheets together and to pass current through the sheets. When the current is passed through the electrodes to the sheets, heat is generated due to the higher electrical resistance where the surfaces contact each other. As the electrical resistance of the material causes a heat buildup in the work pieces between the copper electrodes, the rising temperature causes a rising resistance, and results in a molten pool contained most of the time between the electrodes. As the heat dissipates throughout the workpiece in less than a second (resistance welding time is generally programmed as a quantity of AC cycles or milliseconds) the molten or plastic state grows to meet the welding tips. When the current is stopped the copper tips cool the spot weld, causing the metal to solidify under pressure. The water cooled copper electrodes remove the surface heat quickly, accelerating the solidification of the metal, since copper is an excellent conductor. Resistance spot welding typically employs electrical power in the form of direct current, alternating current, medium frequency half-wave direct current, or high-frequency half wave direct current.

If excessive heat is applied or applied too quickly, or if the force between the base materials is too low, or the coating is too thick or too conductive, then the molten area may extend to the exterior of the work pieces, escaping the containment force of the electrodes (often up to 30,000 psi). This burst of molten metal is called expulsion, and when this occurs the metal will be thinner and have less strength than a weld with no expulsion. The common method of checking a weld's quality is a peel test. An alternative test is the restrained tensile test, which is much more difficult to perform, and requires calibrated equipment. Because both tests are destructive in nature (resulting in the loss of salable material), non-destructive methods such as ultrasound evaluation are in various states of early adoption by many OEMs.

The advantages of the method include efficient energy use, limited workpiece deformation, high production rates, easy automation, and no required filler materials. When high strength in shear is needed, spot welding is used in preference to more costly mechanical fastening, such as riveting. While the shear strength of each weld is high, the fact that the weld spots do not form a continuous seam means that the overall strength is often significantly lower than with other welding methods, limiting the usefulness of the process. It is used extensively in the automotive industry – cars can have several thousand spot welds. A specialized process, called shot welding, can be used to spot weld stainless steel.

There are three basic types of resistance welding bonds: solid state, fusion, and reflow braze. In a solid state bond, also called a thermo-compression bond, dissimilar materials with dissimilar grain structure, e.g. molybdenum to tungsten, are joined using a very short heating time, high weld energy, and high force. There is little melting and minimum grain growth, but a definite bond and grain interface. Thus the materials actually bond while still in the solid state. The bonded materials typically exhibit excellent shear and tensile strength, but poor peel strength. In a fusion bond, either similar or dissimilar materials with similar grain structures are heated to the melting point (liquid state) of both. The subsequent cooling and combination of the materials forms a “nugget” alloy of the two materials with larger grain growth. Typically, high weld energies at either short or long weld times, depending on physical characteristics, are used to produce fusion bonds. The bonded materials usually exhibit excellent tensile, peel and shear strengths. In a reflow braze bond, a resistance heating of a low temperature brazing material, such as gold or solder, is used to join either dissimilar materials or widely varied thick/thin material combinations. The brazing material must “wet” to each part and possess a lower melting point than the two workpieces. The resultant bond has definite interfaces with minimum grain growth. Typically the process requires a longer (2 to 100 ms) heating time at low weld energy. The resultant bond exhibits excellent tensile strength, but poor peel and shear strength.

Seam welding

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"Seam welding" redirects here. For the geometrical welding configuration, see welding joint.

Resistance seam welding is a process that produces a weld at the faying surfaces of two similar metals. The seam may be a butt joint or an overlap joint and is usually an automated process. It differs from flash welding in that flash welding typically welds the entire joint at once and seam welding forms the weld progressively, starting at one end. Like spot welding, seam welding relies on two electrodes, usually made from copper, to apply pressure and current. The electrodes are often disc shaped and rotate as the material passes between them. This allows the electrodes to stay in constant contact with the material to make long continuous welds. The electrodes may also move or assist the movement of the material.

A transformer supplies energy to the weld joint in the form of low voltage, high current AC power. The joint of the work piece has high electrical resistance relative to the rest of the circuit and is heated to its melting point by the current. The semi-molten surfaces are pressed together by the welding pressure that creates a fusion bond, resulting in a uniformly welded structure. Most seam welders use water cooling through the electrode, transformer and controller assemblies due to the heat generated.

Seam welding produces an extremely durable weld because the joint is forged due to the heat and pressure applied. A properly welded joint formed by resistance welding can easily be stronger than the material from which it is formed.

A common use of seam welding is during the manufacture of round or rectangular steel tubing. Seam welding has been used to manufacture steel beverage cans but is no longer used for this as modern beverage cans are primarily seamless aluminum with a glued and curled radial joint.

There are two modes for seam welding: Intermittent and continuous. In intermittent seam welding, the wheels advance to the desired position and stop to make each weld. This process continues until the desired length of the weld is reached. In continuous seam welding, the wheels continue to roll as each weld is made.

Low-frequency electric resistance welding

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Low-frequency electric resistance welding (LF-ERW) is an obsolete method of welding seams in oil and gas pipelines. It was phased out in the 1970s but as of 2015 some pipelines built with this method remained in service.[3]

Electric resistance welded (ERW) pipe is manufactured by cold-forming a sheet of steel into a cylindrical shape. Current is then passed between the two edges of the steel to heat the steel to a point at which the edges are forced together to form a bond without the use of welding filler material. Initially this manufacturing process used low frequency AC current to heat the edges. This low frequency process was used from the 1920s until 1970. In 1970, the low frequency process was superseded by a high frequency ERW process which produced a higher quality weld.

Over time, the welds of low frequency ERW pipe were found to be susceptible to selective seam corrosion, hook cracks, and inadequate bonding of the seams, so low frequency ERW is no longer used to manufacture pipe. The high frequency process is still being used to manufacture pipe for use in new pipeline construction.[4]

Other methods

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Other ERW methods include flash welding, resistance projection welding, and upset welding.[5]

Flash welding is a type of resistance welding that does not use any filler metals. The pieces of metal to be welded are set apart at a predetermined distance based on material thickness, material composition, and desired properties of the finished weld. Current is applied to the metal, and the gap between the two pieces creates resistance and produces the arc required to melt the metal. Once the pieces of metal reach the proper temperature, they are pressed together, effectively forge welding them together.[6]

Projection welding is a modification of spot welding in which the weld is localized by means of raised sections, or projections, on one or both of the workpieces to be joined. Heat is concentrated at the projections, which permits the welding of heavier sections or the closer spacing of welds. The projections can also serve as a means of positioning the workpieces. Projection welding is often used to weld studs, nuts, and other threaded machine parts to metal plate. It is also frequently used to join crossed wires and bars. This is another high-production process, and multiple projection welds can be arranged by suitable designing and jigging.[7]

See also

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References

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Further reading

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Revisions and contributorsEdit on WikipediaRead on Wikipedia

Electric resistance welding

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from Grokipedia
Electric resistance welding (ERW) is a family of processes that join metals by passing an through the workpiece, generating via electrical resistance at the joint interface, and applying to the materials together without filler metals or fluxes. The is produced according to Joule's law (H = I²Rt, where I is current, R is resistance, and t is time), primarily at the contact points between workpieces or electrodes, causing localized melting or plastic deformation to form a strong bond upon cooling. Invented in 1885 by Elihu Thomson, who received patents for the technique, ERW has evolved into a high-speed, automated method widely used in since the early . Key principles include controlling current, electrode force, and weld time to balance heat generation and avoid defects like expulsion or cracking, with electrodes typically used to conduct current while minimizing their own heating. Common types encompass for discrete points on overlapping sheets, seam welding for continuous leak-proof joints using rotating wheel electrodes, projection welding for targeted welds on embossed features, and flash or for end-to-end joining of rods or wires. ERW offers advantages such as rapid cycle times (often under 1 second per weld), low material distortion, and suitability for in , making it economical for joining similar or dissimilar metals like , aluminum, and alloys up to several millimeters thick. Its primary applications include automotive body assembly (e.g., thousands of spot welds per ), components, appliances, , and electrical enclosures, though limitations like high initial equipment costs and challenges with highly conductive materials can restrict its use. Quality assessment often relies on non-destructive methods such as or lobe curve analysis to ensure weld nugget integrity.

Principles of Operation

Heat Generation Mechanism

Electric resistance welding generates heat through the application of Joule's law, which describes the conversion of into due to resistance in the welding circuit. The instantaneous power dissipated as heat, PP, is given by P=I2RP = I^2 R, where II is the welding current in amperes and RR is the total resistance in ohms. Integrating this power over the weld time tt in seconds yields the total heat energy HH generated, approximated as H=I2RtH = I^2 R t for and resistance conditions. The primary source of this resistance—and thus the main heat generation—occurs at the between the faying surfaces of the workpieces, where microscopic asperities and surface s create high localized impedance to current flow. Bulk resistance within the materials contributes only minimally to overall heating, as the current path through the solid metal is relatively low-resistance once established. Factors such as surface contamination, layers, or rough asperities significantly elevate this , concentrating heat at the interface. The heating process unfolds in distinct phases: an initial rapid temperature rise driven by the high at the unsoftened interface, followed by material softening that reduces resistance and shifts heating toward the bulk. Under applied , the softened and molten metal forges together, forming a fusion bond (weld nugget) upon cooling after current termination. To account for heat losses through conduction, , and other mechanisms, the basic is often modified by an efficiency factor KK, resulting in H=I2RtKH = I^2 R t K.

Electrical and Thermal Parameters

In electric resistance welding, the type of electrical current significantly influences distribution and process stability. (AC) at 50-60 Hz is commonly used due to its simplicity and cost-effectiveness, providing a sinusoidal that suits general fusion welding applications. (DC), often delivered via medium-frequency inverters operating at 400-4000 Hz, offers precise control over input through unidirectional flow, resulting in more uniform heating and reduced risk of molten metal expulsion compared to AC. , typically from capacitive discharge systems with pulse durations of 1-16 milliseconds, enables localized heating for delicate materials, minimizing expulsion risks by limiting exposure time. The interplay between voltage and resistance determines the generation at the weld interface, governed by low secondary voltages of 2-20 combined with high currents up to 100,000 A. The total circuit resistance comprises bulk resistance of the workpieces, at the faying surfaces and electrode-workpiece interfaces, and secondary circuit resistance from electrodes and leads. Typical interface ranges from 20-100 micro-ohms per contact, influenced by surface conditions such as oxidation and roughness, which can decrease under applied force. Higher promotes concentrated heating at the interface, while total circuit resistance affects overall energy efficiency. The thermal cycle in resistance welding consists of preheating, nugget formation, and cooling phases, with temperatures varying by material. During preheating, interface temperatures rise to soften asperities; nugget formation occurs as temperatures reach 800-1400°C for steels, initiating fusion at the and growing the molten zone. Cooling follows current termination, solidifying the nugget while forming a (HAZ) typically 0.2-1 mm wide, where microstructural changes occur without melting. temperatures peak at 400-450°C during the cycle, influencing heat balance. Weld timing and electrode force are critical for controlling heat input and mechanical integrity. Squeeze time, lasting 0.15-2 seconds, allows electrodes to apply and stabilize contact before current flow. Weld time ranges from 0.1-1 second (or 6-20 cycles at 60 Hz), during which current generates the nugget. Hold time of 0.5-2 seconds maintains force post-weld to promote solidification and prevent defects. Electrode force for thin sheet metals is typically 2-10 kN, compressing the interface to reduce resistance and expulsion while ensuring adequate contact area. Higher forces shift heat distribution toward bulk heating. Key quantitative benchmarks include a minimum of 10,000-30,000 A/cm² at the contact for reliable fusion in steels, ensuring sufficient for nugget initiation. Power requirements for automotive spot welds generally fall between 20-150 kVA, depending on sheet thickness and cycle demands, with higher ratings supporting rapid production rates.

Equipment and Setup

Key Components

Electric resistance welding (ERW) systems rely on specialized hardware to deliver electrical current, apply precise , and manage dissipation, ensuring consistent weld quality across various processes. Central to these systems are the , which serve as the primary interface for current conduction and force application. Typically constructed from high-conductivity alloys such as RWMA Class 2 Cu-Cr-Zr (C18150), electrodes offer a balance of electrical conductivity, thermal resistance, and mechanical durability, making them suitable for demanding environments like coated and uncoated steels. Electrode shapes vary by application: domed or truncated configurations are common for to concentrate current at the , while rotating wheel-shaped electrodes are used in seam for continuous contact. Typical electrode diameters range from 6 to 16 mm, allowing adaptability to workpiece thickness and material properties. The power supply forms the electrical backbone of ERW equipment, converting line voltage into the low-voltage, high-current output required for localized heating. Welding transformers, often single-phase step-down units, reduce input voltages (typically 220-480 V) to secondary outputs of 1-10 V, enabling currents up to tens of thousands of amperes while minimizing arc risk. For applications needing stable current profiles, rectifiers convert AC to DC, reducing electrode wear and improving nugget formation in materials like aluminum. Stored-energy banks provide alternative high-power pulses for precision welding, discharging stored rapidly to suit short-cycle processes without drawing continuous line power. Transformer efficiencies in these systems generally range from 90% to 95%, reflecting optimized core designs that limit losses during intermittent high-duty operations. Clamping and mechanisms ensure intimate contact between workpieces and electrodes, directly influencing resistance and distribution. Pneumatic presses, utilizing air cylinders or air-over-oil systems, deliver forces from 1 to 50 kN, suitable for high-volume production where rapid cycling is essential. Servo-electric presses offer precise control via electric motors, enabling programmable profiles that adapt to varying material stacks and reduce compared to pneumatic alternatives. In automated setups, these mechanisms integrate with robotic arms, allowing flexible positioning and consistent application in three-dimensional assemblies, such as automotive body-in-white construction. Effective cooling is vital to prevent electrode softening and maintain process stability, as excessive heat can degrade contact resistance over time. Water circulation systems pump coolant through internal channels in electrodes and holders at rates of 2-5 L/min per electrode, dissipating Joule heating and extending component longevity. Electrode dressers, often rotary tools with carbide cutters, are used to perform tip dressing, particularly in resistance spot welding (RSW), machining the electrode tips to restore their shape and performance by removing a controlled amount of deformed material. In RSW, tip dressing schedules typically specify parameters such as "cut amount," "dress depth," or "length of cut" to control the material removed per operation, ensuring consistent electrode face diameter and uniform current density for reliable weld quality. Under optimal conditions, RWMA Class 2 electrodes achieve a service life of 10,000 to 100,000 welds before requiring dressing or replacement, depending on material compatibility and maintenance frequency.

Process Control and Monitoring

Process control and monitoring in electric resistance welding ensure consistent weld quality by providing real-time feedback on key parameters such as electrical resistance, current, voltage, and mechanical force. These systems detect deviations during the welding cycle, allowing for immediate adjustments to prevent defects like incomplete fusion or expulsion. Monitoring techniques primarily rely on dynamic electrical signals, while control mechanisms use feedback loops to maintain optimal conditions. One primary monitoring method involves dynamic resistance curve analysis, where the resistance between electrodes is measured throughout the weld cycle to detect nugget formation. As heat generates a molten nugget, the resistance typically decreases after an initial peak, with characteristic phases indicating proper fusion; deviations, such as prolonged high resistance, signal issues like poor fit-up or electrode misalignment. This approach enables inline estimation of nugget diameter using techniques like and multilinear regression on resistance data, achieving a of approximately 0.33 mm compared to reference measurements. Current and voltage waveforms complement this by revealing anomalies in power delivery, such as spikes that precede expulsion. Control systems employ closed-loop servo mechanisms to regulate and current dynamically, ensuring precise input despite variations in or setup. Servo-driven actuators maintain constant by adjusting for part thickness changes or misalignment, while feedback sensors monitor and correct current levels every 10-250 microseconds in modes like or constant power. Adaptive scheduling algorithms compensate for by analyzing resistance curves and adjusting weld schedules in real-time, extending electrode life and stabilizing nugget growth. For instance, pre-weld ramps prevent sticking, and limits terminate cycles if thresholds are exceeded. Quality metrics focus on nugget size and expulsion avoidance to verify weld integrity. The minimum nugget diameter for steel sheets is typically defined as 5t5\sqrt{t}
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