Arc-jet-power-supply-and-starting-circuit

This circuit for starting arc jets and controlling them in steady operation is capable of high power efficiency and can be constructed in a lightweight form. The design comprises a pulse-width-modulated power converter, which is configured in a closed control loop for fast current control. The series averaging inductor maintains nearly constant current during rapid voltage changes, thereby allowing time for the fast-response regulator to adjust its pulse width to accommodate load-voltage changes. The output averaging inductor doubles as the high-voltage pulse transformer for ignition. The starting circuit operates according to the same principle as that of an automobile ignition coil. When the current is interrupted by a transistor switch, the inductor magnetic field collapses, and a high-voltage pulse is produced. The pulse is initiated every 0.25 seconds until arc current is detected, at which point the pulser is automatically turned off.

The described circuit serves a critical role in the operation of arc jets, which require precise control and efficient energy management. The pulse-width modulation (PWM) technique employed in the power converter allows for effective regulation of the output current, crucial for maintaining stable operation of the arc jet. The closed-loop configuration enhances the responsiveness of the system, enabling it to quickly adapt to changes in load conditions.

The inclusion of a series averaging inductor is significant, as it smooths out current fluctuations that may occur due to rapid voltage changes. This feature is essential for ensuring that the arc jet operates within its optimal parameters, preventing potential damage that could arise from excessive current spikes or drops. The fast-response regulator works in tandem with the inductor, adjusting the pulse width dynamically to maintain the desired current level.

Moreover, the dual function of the output averaging inductor as a high-voltage pulse transformer is an innovative aspect of the design. By utilizing the inductor in this manner, the circuit can generate the necessary ignition pulses to initiate the arc. The operation mimics that of an automobile ignition coil, where a sudden interruption of current leads to a rapid collapse of the magnetic field, resulting in the generation of a high-voltage pulse. This pulse is critical for igniting the arc, and the timing of its generation—every 0.25 seconds—ensures that the system is primed for ignition until the arc current is established.

Once the arc current is detected, the pulser's automatic shut-off feature enhances the efficiency and safety of the circuit, preventing unnecessary energy expenditure and potential overheating. Overall, this circuit design exemplifies a sophisticated approach to managing high-power arc jet operations, blending efficiency with effective control mechanisms to ensure reliable performance.This .circuit for starting arc jets and controlling them in steady operation is capable of high power efficiency and can be constructed in a lightweight form. The design comprises a pulse-width-modulated power converter, which is configured in a closed control loop for fast current control.

The series averaging inductor maintains nearly constant current during rapid voltage changes, and thereby allows time for the fastresponse regulator to adjust its pulse width to accommodate load-voltage changes. The output averaging inductor doubles as the high"voltage pulse transformer for ignition. The starting circuit operates according to the same principle as that of an automobile ignition coil. When the current is interrupted bY a transistor switch, the inductor magnetic field collapses, and a high-voltage pulse is produced.

The pulseis initiated every 0.25 second until arc current is detected, then the pulser is automatically turned off. 🔗 External reference