The diaphragm of the electromagnetic pulse valve divides the right-angle electromagnetic pulse valve into two gas chambers. When the electromagnetic pulse valve is connected to clean compressed air in the pulse bag dust removal system, the compressed air passes through the throttle hole and enters the rear gas chamber. At this point, the pressure in the rear gas chamber presses the diaphragm tightly against the valve's exhaust outlet, keeping the pulse valve closed. The pulse control instrument outputs a signal to move the armature, opening the exhaust vent of the rear gas chamber. The rear gas chamber rapidly depressurizes, causing the diaphragm to move backward. Compressed air is then ejected through the valve's exhaust outlet, and the pulse valve is in the open state, starting the blowing. The electrical signal from the pulse control instrument disappears, the electromagnetic pilot head armature of the pulse valve resets, the exhaust vent closes, the pressure in the rear gas chamber rises, and the pulse valve diaphragm is tightly sealed against the exhaust outlet, returning the pulse valve to the closed state, stopping the blowing. The duration and volume of the blowing are controlled by the control instrument.

The DMF-Z-40S electromagnetic pulse valve with DC24V not only determines the actual blowing air volume based on the connection diameter size, but often cannot judge its dust removal function solely by the interface size. Our solid and sincere footprint is evident in industries such as steel metallurgy, non-ferrous metallurgy, intelligent automatic control systems, construction cement, chemicals, dust removal equipment for severe enterprises, industrial boilers and power stations, as well as in urban waste incineration, bag dust removal equipment, and environmental protection equipment industries. This expands your selection range, making it a viable option for converting from electric to bag systems. The pulse valve handle is jammed at a certain position within the valve seat bore (not the sealing position), causing the piston to always be under pressure due to the significant difference between the input and output media. Therefore, a valve with a diameter appropriate to the valve diameter should be selected. It is sensitive and reliable, widely applicable, and commonly used. When the pressure of the steam drum or superheater exceeds the specified value, steam passes through the impulse conduit and valve into the pulse spring safety valve, lifting the valve core. Through the pulse spring safety valve, the steam then enters the upper part of the main safety valve piston, causing the piston to move downward, opening the main safety valve, and allowing steam to be released and depressurized.