An arc welding system includes a welding power supply. An auxiliary power supply supplies electrical energy to an auxiliary load. An engine-generator is connected to the welding power supply and auxiliary power supply. An engine starting battery is connected to the auxiliary power supply to supply electrical energy thereto during starting of the engine-generator. An auxiliary load sensor is configured to detect a presence of an electrical load on the auxiliary power supply. A speed sensor is configured to sense a speed of the engine-generator. A controller is configured to receive a signal indicating presence of the electrical load on the auxiliary power supply and a signal corresponding to speed of the engine-generator. When presence of the electrical load on the auxiliary power supply is detected, the controller starts the engine-generator, and after the engine-generator has reached a predetermined speed, switches the auxiliary power supply from the battery to the engine-generator.

BACKGROUND OF THE INVENTION

Field of the Invention

The present invention relates to an arc welder powered by a generator and having an auxiliary power output for suppling electrical energy to auxiliary loads, such as lights, power tools, and the like.

Description of Related Art

Arc welding machines can be powered by engine-generators, allowing the arc welding machines to be operated independent of a source of utility power. Such arc welding machines can have auxiliary power outputs (e.g., outlets) that allow other electrical devices (auxiliary loads) to be operated. Certain auxiliary loads may operate intermittently, and it can be wasteful to keep the engine-generator running when an auxiliary load is off. To conserve fuel, the engine-generator can be turned off when the auxiliary load is not on or active; however, the engine-generator will then have to be turned back on when the auxiliary load is subsequently operational. It would be desirable to provide an arc welding system having an engine-generator and auxiliary outputs powered by the engine-generator, in which the engine-generator can be automatically started and stopped based on the power requirements of the auxiliary load.

BRIEF SUMMARY OF THE INVENTION

The following summary presents a simplified summary in order to provide a basic understanding of some aspects of the systems and methods discussed herein. This summary is not an extensive overview of the systems and methods discussed herein. It is not intended to identify critical elements or to delineate the scope of such systems and methods. Its sole purpose is to present some concepts in a simplified form as a prelude to the more detailed description that is presented later.

Example aspects and embodiments of the present invention are summarized below. It is to be appreciated that the example aspects and/or embodiments may be provided separately or in combination with one another.

In accordance with one aspect of the present invention, provided is an arc welding system. The system includes a welding power supply comprising a switching type power converter. A welding electrode is operatively connected to the switching type power converter to receive electrical energy from the switching type power converter and produce an electric arc from the arc welding system. An auxiliary power supply supplies electrical energy to an auxiliary load through an auxiliary power output of the arc welding system. An engine-generator is operatively connected to the welding power supply and the auxiliary power supply, to supply electrical energy to the welding power supply to produce the electric arc, and to supply further electrical energy to the auxiliary power supply. An engine starting battery is configured for starting the engine-generator. The engine starting battery is operatively connected to the auxiliary power supply to supply electrical energy to the auxiliary power supply during starting of the engine-generator. The engine starting battery is electrically isolated from the welding power supply so as not to supply electrical energy to the welding power supply to produce the electric arc. An auxiliary load sensor is configured to detect a presence of an electrical load on the auxiliary power supply and to output a signal indicating said presence of the electrical load on the auxiliary power supply. A speed sensor is configured to sense a speed of the engine-generator and to output a signal corresponding to the speed of the engine-generator. A controller is configured to receive the signal indicating said presence of the electrical load on the auxiliary power supply and the signal corresponding to the speed of the engine-generator. When said presence of the electrical load on the auxiliary power supply is detected, the controller automatically starts the engine-generator, and after the engine-generator has reached a predetermined speed, automatically switches the auxiliary power supply from the engine starting battery to the engine-generator.

In accordance with another aspect of the present invention, provided is an arc welding system. The system includes a welding power supply comprising a switching type power converter. A welding electrode is operatively connected to the switching type power converter to receive electrical energy from the switching type power converter and produce an electric arc from the arc welding system. An auxiliary power output supplies electrical energy to an auxiliary load. An engine-generator is operatively connected to the welding power supply and the auxiliary power output, to supply electrical energy to the welding power supply to produce the electric arc, and to supply further electrical energy to the auxiliary power output. An engine starting battery is configured for starting the engine-generator. The engine starting battery is operatively connected to supply electrical energy to the auxiliary power output during starting of the engine-generator. The engine starting battery is electrically isolated from the welding power supply so as not to supply electrical energy to the welding power supply to produce the electric arc. An auxiliary load sensor is configured to detect a presence of an electrical load on the auxiliary power output and to output a signal indicating said presence of the electrical load on the auxiliary power output. A speed sensor is configured to sense a speed of the engine-generator and to output a signal corresponding to the speed of the engine-generator. A controller is configured to receive the signal indicating said presence of the electrical load on the auxiliary power output and the signal corresponding to the speed of the engine-generator. When said presence of the electrical load on the auxiliary power output is detected, the controller automatically starts the engine-generator, and after the engine-generator has reached a predetermined operational condition, automatically switches the auxiliary power output from the engine starting battery to the engine-generator.

In accordance with another aspect of the present invention, provided is a non-hybrid arc welding system. The system includes a welding power supply comprising a switching type power converter. A welding electrode is operatively connected to the switching type power converter to receive electrical energy from the switching type power converter and produce an electric arc from the arc welding system. An auxiliary power output supplies electrical energy to an auxiliary load. An engine-generator is operatively connected to the welding power supply and the auxiliary power output, to supply electrical energy to the welding power supply to produce the electric arc, and to supply further electrical energy to the auxiliary power output. An engine starting battery is configured for starting the engine-generator. The engine starting battery is operatively connected to supply electrical energy to the auxiliary power output during starting of the engine-generator. The engine starting battery is electrically isolated from the welding power supply so as not to supply electrical energy to the welding power supply to produce the electric arc. An auxiliary load sensor is configured to detect a presence of an electrical load on the auxiliary power output and to output a signal indicating said presence of the electrical load on the auxiliary power output. A speed sensor is configured to sense a speed of the engine-generator and to output a signal corresponding to the speed of the engine-generator. A controller is configured to receive the signal indicating said presence of the electrical load on the auxiliary power output and the signal corresponding to the speed of the engine-generator. When said presence of the electrical load on the auxiliary power output is detected during a welding interlude, the controller automatically starts the engine-generator, and after the engine-generator has reached a predetermined speed, automatically switches the auxiliary power output from the engine starting battery to the engine-generator. When said presence of the electrical load on the auxiliary power output not detected during said or another welding interlude, the controller automatically stops the engine-generator.

DETAILED DESCRIPTION OF THE INVENTION

The present invention relates to arc welders powered by an engine-generator and having one or more auxiliary power outputs for supplying electrical energy to auxiliary loads. The present invention will now be described with reference to the drawings, wherein like reference numerals are used to refer to like elements throughout. It is to be appreciated that the various drawings are not necessarily drawn to scale from one figure to another nor inside a given figure, and in particular that the size of the components are arbitrarily drawn for facilitating the understanding of the drawings. In the following description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of the present invention. It may be evident, however, that the present invention can be practiced without these specific details. Additionally, other embodiments of the invention are possible and the invention is capable of being practiced and carried out in ways other than as described. The terminology and phraseology used in describing the invention is employed for the purpose of promoting an understanding of the invention and should not be taken as limiting.

As used herein, the term “welding” refers to an arc welding process. Example arc welding processes include shielded metal arc welding (SMAW) (e.g., stick welding), flux cored arc welding (FCAW), and other welding processes such as gas metal arc welding (GMAW), gas tungsten arc welding (GTAW), and the like.

An example arc welding system10is shown schematically inFIG. 1. The welding system10includes a generator12driven by an engine14thereby forming an engine-generator. Example engines include diesel engines, gasoline engines, LP gas engines, and the like. The generator12generates electrical energy for powering a welding power supply16(hereinafter “welder”). The generator12can be a synchronous 3-phase alternator. However, the generator need not be a synchronous 3-phase alternator. For example, the generator could be a single phase alternator or a DC generator if desired. In certain embodiments, the generator12can have auxiliary windings for providing electrical power to auxiliary loads in addition to the welder16.

The welder16includes circuitry for generating a welding waveform during arc welding. A welding operation is schematically shown inFIG. 1as an electric arc18extending between a welding electrode20(consumable or non-consumable) and a workpiece22.

The welder16also includes circuitry for providing AC or DC power to one or more auxiliary power outputs24,26(e.g., Aux1and Aux2inFIG. 1). The auxiliary power outputs24,26are typically powered by the generator12and provide electrical power to auxiliary loads28,30. Example auxiliary loads that can be powered by the welder16include tools, lights, pumps, chargers and the like.

The auxiliary power outputs24,26can include appropriate outlets for facilitating connections to the auxiliary loads28,30. Example outlets include, for example, NEMA standard outlets commonly found in North America, CEE outlets commonly found in Europe, and other styles of outlets. The auxiliary power outputs24,26can include multiple styles of outlets to readily accommodate use in different geographical locations around the world, or the welder16can include appropriate adapters to convert one style of outlet to another.

The output voltage at the auxiliary power outputs24,26is provided by one or more inverters within the welder16. The welder16includes a controller32that is operatively connected to the inverter(s) to control the characteristics (e.g., frequency and voltage level) of the output voltage at the auxiliary power outputs24,26. Through known pulse width modulation techniques, the controller32can provide different voltage levels and frequencies at the auxiliary power outputs24,26. For example, when used in North America, the auxiliary power outputs24,26can be controlled to provide 60 Hz power at a desired voltage level (e.g., 120V, 240V etc.) When used in Europe, the auxiliary power outputs24,26can be controlled to provide 50 Hz power at a desired voltage level (e.g., 220V). Other frequencies and voltages are possible. For example, when used at an airport, the auxiliary power outputs can be controlled to provide 400 Hz power at 120V.

The controller32can be an electronic controller and may include a processor. The controller32can include one or more of a microprocessor, a microcontroller, a digital signal processor (DSP), an application specific integrated circuit (ASIC), a field-programmable gate array (FPGA), discrete logic circuitry, or the like. The controller32can include a memory portion (e.g., RAM or ROM) storing program instructions that cause the controller to provide the functionality ascribed to it herein.

The arc welding system10includes an engine starting battery34for starting the engine14. The engine14can be started automatically by the controller32or manually via appropriate user interface components on engine-generator or welder16. In addition to being operatively connected to the engine14(e.g., connected to a starting motor attached to the engine), the starting battery34is also connected to the welder16to provide temporary power to the auxiliary power outputs24,26while the engine14is starting and before the output voltage of the generator12has reached its proper magnitude and frequency.

The arc welding system10is a non-hybrid welding system. That is, the arc welding system is lacks a battery or bank of batteries for supplying electrical power for welding. The starting battery34is electrically isolated from a welding power supply within the welder16that generates the welding waveform. The starting battery34only supplies electrical power temporarily (e.g., while the engine is starting) to the auxiliary power outputs24,26, but does not supply power for arc welding.

The controller32is operatively connected to the welder16, engine-generator, and optionally the battery (e.g., to monitor battery voltage, current, charge level, etc.) The controller32can determine when an auxiliary load28,30requires power, such as when the auxiliary load turns on and draws current from the battery. If the engine-generator is currently OFF (not running) and an auxiliary load28,30requires power, the controller32will automatically start the engine-generator by sending a start signal to the engine-generator. The engine-generator will generally come up to speed quickly, such as within 60 seconds, 30 seconds, 10 seconds etc., during which time the auxiliary loads will be supplied by the starting battery34. When the engine-generator reaches a predetermined operation condition, such as a proper operating speed, generated voltage level and/or frequency, the controller32automatically switches the auxiliary power outputs24,26from the starting battery34to the generator12, such as by sending an appropriate command signal to an electronic or electromechanical switching device in the welder16.

Some auxiliary loads28,30can turn on automatically and intermittently, making manual activation of the engine-generator inconvenient. For example, if a liquid level-controlled pump (e.g., float switch activated sump pump) is connected to an auxiliary power output24,26, it may attempt to automatically turn on intermittently. If the engine-generator could not be automatically turned ON by the controller32, the engine14could be left running to accommodate the intermittent load, thereby unnecessarily consuming fuel and generating exhaust gasses and noise. To avoid this, the controller32can sense that an auxiliary load28,30is active and start the engine-generator. Moreover, the auxiliary load28,30can be immediately powered by the starting battery34while the engine-generator comes up to speed, thereby avoiding a time lag between the auxiliary load requiring power and the welding system10being able to deliver power when the engine-generator is initially OFF.

During interludes between active welding operations (i.e. during welding interludes), the engine-generator can be turned OFF, ether manually or automatically. During such welding interludes, the auxiliary load28,30may attempt to turn on, in which case the controller32can automatically start the engine-generator during the welding interludes, while the auxiliary load is temporarily powered by the starting battery34. When the engine-generator reaches a predetermined speed (e.g., a predetermined RPM or generator output frequency), the controller automatically switches the auxiliary loads28,30from starting battery power to generator power. The starting battery34will then be recharged while the engine14is operated, either by the generator12or by a separate alternator driven by the engine. When the auxiliary load28,30turns off during a welding interlude, the controller32can sense that the auxiliary load is no longer consuming electrical power and automatically stop the engine14. If the auxiliary load28,30turns on during an active welding operation, the engine-generator should already be running, and the controller32would not attempt to start the engine14.

FIG. 2provides another schematic diagram of an example arc welding system10with additional details. Armature windings in the generator12supply electrical power to a switching type power converter40within the welder. Example switching type power converters include DC choppers, inverters, and the like. AC power from the generator is rectified by a rectifier42within the power converter40. The DC output from the rectifier42supplies the welder's DC bus43. The DC bus43, in turn, supplies electrical power to a switching circuit, such as a chopper or inverter44.

Electrical leads46,48from the chopper/inverter44provide a completed circuit for the arc welding current. The arc welding current flows from the chopper/inverter44through the electrode20, across the arc18, and through the workpiece22. The welding electrode20and workpiece22are operatively connected to the switching type power converter40via the electrical leads46,48. The welding electrode20receives electrical energy from the switching type power converter40(as supplied by the engine-generator) for producing the arc18.

In certain embodiments, controller32is operatively connected to the switching type power converter40to provide control signals to the switching type power converter to control the welding waveform. The controller32can monitor various aspects of the welding process via feedback signals (e.g., welding current/voltage) and adjust welding parameters during arc welding accordingly.

The controller32is further operatively connected to an auxiliary power supply50for supplying electrical energy to the auxiliary load28through the auxiliary power output24. The auxiliary power supply50can include a rectifier/inverter52for converting the AC electrical power received from the generator12and the DC electrical power received from the starting battery34into a desired output voltage (e.g. AC) and frequency for the auxiliary load28. The auxiliary power supply50can include an auxiliary load sensor54that detects the presence of an electrical load on the auxiliary power supply50. The auxiliary load sensor54outputs a signal to the controller32indicating the presence of the electrical load. InFIG. 2, the auxiliary load sensor is shown as a current transformer. However, other types of electrical load sensors could be used, or the auxiliary power supply50could directly communicate the existence of an auxiliary load to the controller, such as via digital communications, a contact closure, etc.

The controller32can control the starting and stopping of the generator12based on demand from the auxiliary load28as discussed above. In particular, the controller32can communicate with start/stop circuitry56in the engine-generator to control the operations of the generator12. The engine-generator can include a speed sensor58(e.g., a tachometer) that senses the speed of the engine or generator and that outputs a corresponding signal to the controller32. The controller32can compare the speed signal from the speed sensor58to a predetermined speed, to determine if the engine-generator has reached the desired operating speed. Rather than directly measuring RPM of the engine-generator, the speed sensor58could measure the output frequency of the generator, and the speed sensor could be located in either the engine-generator or the welder.

Once the engine-generator reaches the correct speed and/or produces the correct output voltage, the controller32can signal the rectifier/inverter52within the auxiliary power supply50to switch from battery power to generator power. In the example arc welding system10shown inFIG. 2, the auxiliary power output24is always supplied through the power electronics within the auxiliary power supply50, rather than directly from the output of the generator. However, if desired, the welder could include appropriate switching circuitry, such as a contactor, for bypassing the rectifier/inverter52, so that the auxiliary power output24is supplied directly from the generator12.

The controller32automatically switches the auxiliary power supply50from the engine starting battery34to the engine-generator fairly quickly, such as within 60 seconds of starting the engine, within 30 seconds, within 10 seconds etc. If the engine-generator does not start within a predetermined time period (e.g., as noted above), or does not operate properly (e.g., no or low output voltage from the generator), the controller32can generate an alarm signal to provide a local or remote alarm60to alert a user.

FIG. 2schematically shows a starting motor62and alternator64connected to the starting battery34and coupled to the engine14. The starting motor62is energized by the battery34via appropriate control circuitry to start the engine14. The alternator64is driven by the engine14to recharge the battery62and provide electrical power to other devices associated with the engine-generator and welder.

FIG. 3provides another schematic diagram of an example arc welding system10. The output from the generator12is provided to the switching type power converter40and the auxiliary power supply50. The auxiliary power supply50includes switching circuitry70for bypassing an inverter52a. The operations of the switching circuitry70are controlled by the controller32, so that the inverter52ais bypassed and the auxiliary power output24is directly connected to the generator12when the engine-generator is running. During engine starting, the switching circuitry70connects the starting battery34to the auxiliary power output24through the inverter52a.

FIG. 4provides another schematic diagram of an example arc welding system10.FIG. 4schematically shows that the generator12can have separate outputs72,74and armature windings for supplying power to the switching type power converter40and the auxiliary power supply50. The generator12can have primary armature windings that supply single or three-phase power to the switching type power converter40, and auxiliary windings that supply power to the auxiliary power supply50.