Industrial wastewater treatment demands advanced solutions. The 400A 50V Single-Pulse Electrocatalytic Rectifier provides precisely that. This high-current power supply is engineered for efficiency. It overcomes the limits of conventional systems effectively.
How does it achieve this? By utilizing innovative single-pulse technology. This method delivers energy in precise bursts. It enhances the electrocatalytic process significantly. The result is superior pollutant degradation.
This single-pulse electrocatalytic rectifier offers clear advantages. It maintains optimal catalyst activity consistently. The 400A output supports large-scale industrial applications. Learn more about its role in our Advanced Oxidation Process Systems.
The technology is grounded in solid science. Research from the Water Environment Federation supports its principles. These principles involve enhanced radical generation. They lead to more complete contaminant destruction.
| Commonly Used Water Treatment Power Supply Models (Custom models are available if not listed in the table). | |||||||
| Model | Output current A | Output voltage V | Power KW | Input current A | Input voltage V | Weight (KG) | Width W * Length L * Height H |
| GH10024 | 100A | 24V | 2.4 | 12 | 220 | 17 | 380*400*170 |
| GH100100 | 100A | 100V | 10 | 17 | 380 | 40 | 450*500*225 |
| GH120100 | 120A | 100V | 12 | 20 | 380 | 40 | 450*500*225 |
| GH20015 | 200A | 15V | 3 | 15 | 220 | 17 | 380*400*170 |
| GH20024 | 200A | 24V | 4.8 | 8 | 380 | 40 | 450*500*225 |
| GH20036 | 200A | 36V | 7.2 | 12 | 380 | 40 | 450*500*225 |
| GH20048 | 200A | 48V | 9.6 | 16 | 380 | 40 | 450*500*225 |
| GH200100 | 200A | 100V | 20 | 33 | 380 | 130 | 510*580*920 |
| GH30024 | 300A | 24V | 7.2 | 12 | 380 | 40 | 450*500*225 |
| GH30036 | 300A | 36V | 10.8 | 18 | 380 | 40 | 450*500*225 |
| GH30048 | 300A | 48V | 14.4 | 24 | 380 | 95 | 510*580*690 |
| GH300100 | 300A | 100V | 30 | 50 | 380 | 130 | 510*580*920 |
| GH33030 | 330A | 30V | 9.9 | 16.5 | 380 | 40 | 450*500*225 |
| GH40030 | 400A | 30V | 12 | 20 | 380 | 40 | 450*500*225 |
| GH50024 | 500A | 24V | 12 | 20 | 380 | 95 | 510*580*690 |
| GH50036 | 500A | 36V | 18 | 30 | 380 | 95 | 510*580*690 |
| GH50048 | 500A | 48V | 24 | 40 | 380 | 95 | 510*580*690 |
| GH50012 | 500A | 12V | 6 | 10 | 380 | 45 | 380*400*170 |
| GH60048 | 600A | 48V | 28.8 | 48 | 380 | 95 | 510*580*920 |
| GH100024 | 1000A | 24V | 24 | 40 | 380 | 95 | 510*580*690 |
| GH100036 | 1000A | 36V | 36 | 60 | 380 | 130 | 510*580*920 |
| GH100048 | 1000A | 48V | 48 | 80 | 380 | 130 | 510*580*920 |
| GH100012 | 1000A | 12V | 12 | 20 | 380 | 45 | 480*525*310 |
| GH200024 | 2000A | 24V | 48 | 80 | 380 | 130 | 510*580*920 |
| GH300024 | 3000A | 24V | 72 | 120 | 380 | 165 | 530*600*1200 |
| GH4000100 | 4000A | 100V | 400 | 667 | 380 | 195 | 580*650*1400 |
| GH800036 | 8000A | 36V | 288 | 480 | 380 | 235 | 600*680*1600 |
| GH1000036 | 10000A | 36V | 360 | 600 | 380 | 260 | 800*1350*1510 |
The water treatment power supply primarily consists of a rectifier-filter circuit, a full-bridge converter circuit, a high-frequency transformer, a high-frequency rectifier-filter circuit, an auxiliary power circuit, and a main control unit. The main control unit circuit mainly comprises phase loss protection, temperature protection, overload protection, short-circuit protection, and a PWM circuit with PI regulation.
The three-phase grid voltage is rectified and filtered after passing through the power switch, yielding a smoothed 520VDC supply for the inverter circuit. The inverter circuit primarily employs high-power MOSFET or IGBT modules to form a full-bridge converter. When the PWM output control signal drives the power modules through isolated drivers, two sets of diagonal transistors conduct alternately. This generates a high-frequency pulse voltage in the primary winding of the high-frequency transformer. The secondary voltage is transformed by the high-frequency transformer, rectified, and then supplies energy to the load.
Industrial wastewater treatment demands significant processing capacity. Traditional systems often struggle with large flow rates. This is where 400A current capacity becomes crucial. It supports high-volume treatment without multiple units. The economic benefit is immediately apparent. Fewer units mean lower capital investment. Operational complexity is also significantly reduced. Maintenance focuses on a single high-capacity system.
Understanding pulse technology requires examining catalyst behavior. Continuous current can deactivate catalytic surfaces over time. Single-pulse operation prevents this deactivation effectively. The 50V pulse creates intense localized fields. These fields enhance hydroxyl radical generation at catalyst sites. Pollutant degradation rates increase substantially. Energy consumption decreases simultaneously. The system achieves more with less input power.
Some industries produce exceptionally challenging wastewater. Pharmaceutical manufacturing is a prime example. Complex organic molecules resist conventional treatment. Chemical plant effluent presents similar difficulties. High salinity often accompanies organic loads. The 400A 50V system tackles these combined challenges. It handles high flow rates reliably. Concurrently, it degrades persistent organic compounds. The result is consistent compliance with strict discharge standards.
Advanced oxidation traditionally carries high operational costs. Chemical oxidant consumption is a major expense. Energy requirements further increase overall costs. The single-pulse system addresses both issues directly. It reduces or eliminates chemical oxidant needs. Energy consumption decreases by 30-50% typically. Electrode lifespan extends due to pulsed operation. Total treatment cost per cubic meter drops significantly. Return on investment becomes clear within months.
