Battery powered welding system

The invention claimed is: 1. A battery powered welder comprising: power conversion circuitry comprising a welding output power conversion circuit configured to convert an input power from an external battery power source to a weld output power based on a reference power level selected by an operator via a weld output control that is adjusted by the operator to provide the reference power level; a wire feed speed control circuitry comprising a pulse width modulation wire drive motor control circuit configured to generate one or more signals to regulate a voltage in a wire drive motor based on a reference wire feed speed level selected by the operator; a wire drive assembly comprising the wire drive motor and one or more wire feed roller, the wire drive assembly communicably coupled to the wire drive motor control circuit and configured to: receive the weld output power from the welding output power conversion circuit to provide the weld output power to a welding torch via at least one weld cable; receive the one or more signals from the wire drive motor control circuit; convert the one or more signals from the wire drive motor control circuit to mechanical energy to turn the one or more wire feed rollers; and feed a welding wire via the one or more wire feed rollers using power from the external battery power source to drive the wire drive motor in response to the one or more signals; and a case integrally supporting and enclosing the power conversion and wire feed speed control circuitry and the wire drive assembly, wherein the power conversion and wire feed speed control circuitry is mounted to a side of the case, and the external battery power source is not enclosed within the case of the welder, wherein the case comprises a user interface disposed within the case and configured to receive inputs from the operator setting one or more welding parameters, wherein the case defines a storage area surrounding the wire drive assembly and the power conversion and wire feed speed control circuitry, wherein the storage area is configured to store the welding torch, the at least one weld cable, and at least one battery cable about the wire drive assembly and the power conversion and wire feed speed control circuitry. 2. The welder of claim 1 , comprising a cooling fan configured to aid in dissipating heat generated by the power conversion and wire feed speed control circuitry, wherein the power conversion and wire feed speed control circuitry comprises a fan controller configured to control the operation of the cooling fan. 3. The welder of claim 1 , comprising a gas valve configured to control a flow of gas to the welding torch. 4. A battery powered welding system comprising: a case configured to support and enclose the welding system; a MIG torch for performing a welding operation; a first battery cable configured to be coupled between the case and a first terminal of an external battery power source; a second battery cable configured to be coupled between the case and a second terminal of the external battery power source; power conversion circuitry comprising a welding output power conversion circuit configured to convert an input power from the external battery power source to a weld output power based on a reference power level selected by an operator via a weld output control that is adjusted by the operator to provide the reference power level; a wire feed speed control circuitry comprising a pulse width modulation wire drive motor control circuit configured to generate one or more signals to regulate a voltage in a wire drive motor based on a reference wire feed speed level selected by the operator; and a wire drive assembly comprising the wire drive motor and one or more wire feed roller, the wire drive assembly communicably coupled to the wire drive motor control circuit and configured to: receive the weld output power from the welding output power conversion circuit to provide the weld output power to the MIG torch via at least one weld cable; receive the one or more signals from the wire drive motor control circuit; convert the one or more signals from the wire drive motor control to mechanical energy to turn one or more wire feed rollers; and feed a welding wire using power from the external battery power source in response to the one or more signals; wherein the case comprises a user interface disposed within the case and configured to receive inputs from the operator selecting a reference power level, a reference wire feed speed level, or a combination thereof, wherein the case defines a storage area surrounding the wire drive assembly and the power conversion and wire feed speed control circuitry, wherein the storage area is configured to store the MIG torch, the first and second battery cables, and the weld cable about the wire drive assembly and the power conversion and wire feed speed control circuitry, and the external battery power source is not enclosed within the case of the welder. 5. The system of claim 4 , comprising a work cable configured to be coupled to the case. 6. The system of claim 4 , comprising the weld cable configured to couple the MIG torch to the case. 7. The system of claim 4 , wherein the case comprises a louver configured to dissipate heat produced by the wire feed speed control circuitry. 8. An externally powered metal inert gas (MIG) welder comprising: power conversion and control circuitry comprising: a welding power converter configured to receive power from an external battery power source; a weld output controller configured to control welding power output of the welding power converter based on a reference power level selected by an operator; a wire feed speed control circuitry comprising a pulse width modulation wire drive motor control circuit configured to generate one or more signals to control a wire drive assembly based on a reference wire feed speed level selected by the operator via the wire feed speed control circuitry; and one or more control inputs configured to received adjustments to one or more welding parameters; a single input contactor comprising a coil, wherein power is inhibited from flowing through the single input contactor to the welding power converter and the pulse width modulation wire drive motor control circuit while the coil is de-energized, wherein power from the external battery power source flows through the single input contactor while the coil is energized; a wire drive assembly comprising the wire drive motor and one or more wire feed roller, the wire drive assembly communicably coupled to the wire drive motor control circuit and coupled to the power conversion and control circuitry and configured to feed a welding wire using power from the external battery power source; a housing enclosing the power conversion and control circuitry and the wire drive assembly, wherein the power conversion and control circuitry is mounted to a side of the housing, and the external battery power source is not enclosed within the case of the welder, wherein the housing defines a storage area surrounding the wire drive assembly and the power conversion and control circuitry, wherein the storage area is configured to store a welding torch, and at least one weld cable about the wire drive assembly and the power conversion and control circuitry; and a polarity change-over device configured to reverse a polarity of the welding output power between a work clamp cable and the welding torch, wherein the wire drive assembly is further configured to provide the received welding output power to the welding torch from the polarity change-over device. 9. The welder of claim 8 , comprising a fan controller configured to control the operation of a cooling fan using th