Electronic processor

　　Electronic Water Treatment Device

　　The electronic water treatment device is one of the cutting-edge technologies in the global water industry today. Since the 1980s, it has been widely adopted in industrially advanced countries for water systems such as cooling circuits, heat exchangers, and hot-water boilers. Our company has not only assimilated and absorbed advanced technologies from both domestic and international sources but has also conducted in-depth, meticulous research on this technology, achieving breakthrough progress. According to our calculations: compared with chemical treatment methods, it can reduce equipment investment by 60%–70%, conserve water by 80%, increase efficiency by more than 18%, save 1,300 kWh of electricity per ton of water treated annually, and keep operating costs at only about 1/350 of the conventional level. Just from energy and water savings alone, the entire investment can be recouped within a single year. Even more advantageous are its zero pollution, long service life—over 15 years of continuous operation—and the fact that a one-time investment yields benefits for many years to come.

　　Selection Table

Model	Inlet and outlet diameter		Weight (kg)	Input power w	Flow rate t/h
Model	in	Mm	Weight (kg)	Input power w	Flow rate t/h
YJ- S C-2	2	50	35	25	19
YJ -SC-2.5	2.5	65	50	25	28
YJ- S C-3	3	80	50	50	50
YJ- SC-4	4	100	50	50	80
YJ-SC-5	5	125	70	70	125
YJ- SC-6	6	150	70	70	180
Y J-SC-8	8	200	80	80	320
Y J-SC-10	10	250	90	120	490
YJ-SC-12	12	300	120	210	710
Y J-SC-14	14	350	130	250	1000
YJ- S C-16	16	400	150	330	1400
YJ-SC-18	18	450	180	410	1600
YJ- SC-20	20	500	200	500	1970
YJ- S C-24	24	600	260	660	2850
YJ- S C-28	28	700	320	900	3800

　　Product Overview

　　Scale formed in water after heating is primarily composed of hardness scale, which consists of calcium and magnesium ions. An electronic water treatment device employs a physical method: high-frequency waves increase the polarity of water molecules, altering the arrangement of scaling ions and thereby preventing calcium and magnesium ions from forming crystal nuclei, thus achieving scale inhibition. Moreover, these high-frequency waves can resonate with existing scale, facilitating its removal. In addition, the electronic water treatment device also possesses bactericidal and algaecidal functions.

　　Scope of Application

　　Numerous applications, including municipal water supply, chilled water, cooling water, heating water, bathing water, groundwater, swimming pool water, and industrial recirculating water.

　　Technical Features

　　Mechatronic integrated design: compact footprint, high flow rate, purely physical treatment process that does not contaminate water quality, extremely low operation and maintenance costs, simple operation, and convenient maintenance.

　　Functional Parameters

　　Pressure loss: ≤0.02 MPa Power supply: 220 V ±10%, 50–60 Hz

　　Safety insulation voltage: 5000 V. Operating environment requirements: -25°C to +50°C, relative humidity ≤95%.

　　Scale prevention and removal efficiency ≥ 90%; bactericidal and algaecidal efficacy ≥ 90%.

　　Working medium temperature: 0 to +90°C; Power consumption: ≤340 W

　　Water quality adaptation: Total hardness ≤ 700 mg/L (as CaCO₃); Mean Time Between Failures: Not less than 50,000 hours.

Serial Number	Project	Source Clean Features	Characteristics of Domestic Branches	Additional Notes
1	Shielding Mesh and Its Function	This product generates an alternating electromagnetic field by establishing a circuit between the electrode (positive pole) and the metal pipe wall (negative pole). Since both electrodes are positive, the principle of like charges repelling each other is utilized to achieve shielding and isolation, ensuring that each electrode operates independently without frequency interference.	Without shielding mesh isolation, the treatment effect is confined to the outer side of the electrodes; on the inner side, the mutual repulsion of the electromagnetic fields creates a “vacuum” zone, rendering it incapable of treating the water quality.	30% higher water treatment efficiency compared with domestic peers
2	Electrode material	Made from a special alloy material	Made of copper	Electrodes made from special alloy materials have a service life 5 to 7 times longer than those made from copper.
3	Connection method between the circuit board and the electrode	A shielded connection employing a special manufacturing process ensures that the generated energy is efficiently delivered to the electrode.	Using the direct-connection method: 1. Prolonged use can easily lead to poor contact; 2. Since shielded cables are not used, there is significant interference with external electrical equipment.	The connection method exhibits frequency and functional losses that are minimized to the greatest extent compared with domestic counterparts.
4	Entrance and Exit Design	Install a flow guide to induce rotational flow.	This device does not exist.
5	Selection of Electronic Components	The transformer utilizes a specialized “R”-type design, making it suitable for reliable operation in harsh environments—even underwater—and all electronic components are 100% imported.	The transformer uses laminated steel laminations, resulting in poor high-temperature and humidity resistance, and its electronic components are imported.	Designed for humid environments such as air-conditioning machine rooms and rooftop outdoor units, with a low repair rate.
6	Protective devices for the host	Patented temperature-control design ensures that the host unit’s operating temperature does not exceed 40°C.	When the host is operating, the temperature exceeds 50°C.	The host’s service life is 3–5 times longer than that of comparable manufacturers.
7	Design of Wastewater Discharge Outlets	Install additional sewage discharge outlets to address users’ difficulties in wastewater disposal.	This device does not exist.
8	Rich machine cavity	The inner wall of the furnace tube is treated with a special phosphating process.	None	Increase the magnetic field strength