Provided are: an arc welding method that suppresses occurrences of blow holes in initial parts and final parts in a Zn plated steel sheet and reduces the occupancy ratio for blow holes in the welded part as a whole; and a welded joint.

A method and apparatus are provided for late-customization of a valve body having an initial valve body configuration having a first end connection and a second end connection. The method includes receiving a selection of (i) a generic valve body, (ii) a first end connection, and (iii) a second end connection. The method further includes adjoining the first and second end connections to the valve body using an iterative welding process. The apparatus is configured to receive a generic valve body having an initial end configuration and to receive a different end configuration. Ends are connected to the valve body subject to an initial bias and a comparison between actual results and predicted results, and first end connection is iteratively welded.

An metal fabrication resource performance monitoring method includes: acquiring data representative of arc on time and wire deposition quantity associated with metal fabrication operations of a plurality of metal fabrication resources; via at least one computer processor, analyzing a first subset of the acquired data and a second subset of the acquired data for the plurality of metal fabrication resources; via the at least one computer processor, populating a user viewable page with graphical indicia representative of at least the arc on time and the wire deposition quantity, the user viewable page facilitating a visual comparison of the analysis of the first subset of the acquired data and the analysis of the second subset of the acquired data; and transmitting the user viewable page to a user viewable display.

A method comprises: providing a welding current pulse through a welding circuit to create an arc for a welding operation; measuring an arc voltage to produce a measured arc voltage pulse that includes an inductive voltage drop due to inductance in the welding circuit and current ramps of the welding current pulse; and during the welding operation, implementing an inductance-compensation feedback loop. The feedback loop includes canceling the inductive voltage drop from the measured arc voltage pulse using a canceling voltage to produce a compensated arc voltage pulse; and deriving the canceling voltage based on the compensated arc voltage pulse.

A multi-process welding machine provides an intuitive user interface to enable a user to select among different welding processes, and to select parameters for a given selected welding process. The multi-process welding machine also provides an arrangement by which a switching module, or DC to AC converter, of an AC TIG unit can be controlled to alternatively supply AC or DC welding voltages or current. Further, a configuration of switches can be leveraged to automatically (or manually) control the polarity of welding cables for different processes and to engage or disengage a wire feeder when, e.g., a MIG welding process is selected, or not selected, respectively. Finally, in an embodiment, the ferrite or magnetic materials used for a main output inductor and an high frequency starting inductor of the welding machine can be combined.

In order to develop a welding process in such a way that uniform flaking of a weld seam can be guaranteed even with a higher number of short-circuit cycles, a specific number of short-circuit cycles is specified for the cold welding phase and the cold phase duration of the cold welding phase is determined for a number of short-circuit cycles that exceeds a specified limit cycle number, depending on a determined cold phase time and after the cold welding phase, there is a switch to the hot welding phase.

A welding system (1) comprising a main module (2) equipped with an external casing (3) in which an inlet port (4) for the connection to an external electric power source, an electric generator (5) configured to adapt the electrical characteristics of the electric power received at the inlet to a first type of welding, an outlet port (6) for the connection by means of an electric conductor (10) to a welding torch (20) and an electronic control unit (7) configured to control the functionality of the electric generator (5) are identified. The welding system also comprises a welding torch (20) configured to be connected by means of the electrical conductor (10) to the outlet port (6).

Provided is an arc welding device that performs welding by alternately repeating a short-circuit period provided with a short-circuit state in which a welding wire and a base material are short-circuited, and an arc period provided with an arc state in which an arc is generated between the welding wire and the base material. A calculation unit calculates an integrated power value by integrating power supplied to the welding wire within a predetermined period, after the welding wire is short-circuited. A controller reduces a welding current to be supplied to welding wire when the integrated power value is larger than a predetermined threshold.

In arc welding in which a welding wire serving as a consumable electrode is fed toward a base material and a welding current is caused to flow through the welding wire and the base material to alternately repeat a reverse polarity period and a positive polarity period, after a short circuit between the welding wire and the base material is detected, a feeding speed of the welding wire is changed from a first feeding speed to a second feeding speed on a negative side of the first feeding speed when a speed in a direction toward the base material is defined as positive.

Arc welding, in which a welding wire serving as a consumable electrode is fed toward a base material and a welding current alternately including a peak current and a base current is caused to flow through the welding wire and the base material, is performed such that after a short-circuit between the welding wire and the base material is detected, a feeding speed of the welding wire is changed from a first feeding speed to a second feeding speed that is on a negative side from the first feeding speed when a speed in a direction in which the welding wire is fed toward the base material is defined as positive.