Wilkerson Filter M08 Series Wilkerson Agent

Wilkerson Filter M08 Series Wilkerson Agent

During operation, the turbid liquid enters the lower chamber of the filter through the inlet and then enters the inner cavity of the filter element through the partition hole. Impurities larger than the gap of the filter element are intercepted, and the clean liquid passes through the gap to reach the upper chamber and is sent out from the outlet. The filter adopts a high-strength wedge-shaped filter screen, which automatically cleans the filter element through pressure difference control and timed control. When impurities accumulate on the surface of the filter element, causing the pressure difference between the inlet and outlet to increase to the set value, or when the timer reaches the preset time, the electric control box sends a signal to drive the backwash mechanism. When the backwash suction is aligned with the inlet of the filter element, the drain valve opens, and the system releases pressure and drains water. A negative pressure zone with a relative pressure lower than the water pressure outside the filter element appears between the suction cup and the inside of the filter element, forcing some of the clean circulating water to flow from the outside of the filter element into the inside of the filter element. Impurities and particles adsorbed on the inner wall of the filter element flow into the tray with the water and are discharged from the drain valve. The specially designed filter creates a jet effect inside the filter element, and any impurities will be washed away from the smooth inner wall. When the pressure difference between the inlet and outlet of the filter returns to normal or the timer set time ends, the material does not stop flowing throughout the entire process, and the backwash consumes less water, achieving continuous and automated production. Filters are widely used in metallurgy, chemical industry, petroleum, papermaking, medicine, food, mining, electricity, and urban water supply fields.

The water to be treated by the filter enters the body through the inlet, and impurities in the water deposit on the stainless steel filter screen, resulting in a pressure difference. By monitoring the pressure difference at the inlet and outlet through a pressure difference switch, when the pressure difference reaches the set value, the electronic controller sends a signal to the hydraulic control valve and drives the motor. After installation, the equipment is debugged by technicians to set the filtration time and cleaning conversion time. The water to be treated enters the body through the inlet, and the filter starts to work normally. When the preset cleaning time is reached, the electronic controller sends signals to the hydraulic control valve and the driving motor, triggering the following actions: the motor drives the brush to rotate, cleaning the filter element, and at the same time, the control valve opens for sewage discharge. The entire cleaning process only lasts for a few tens of seconds. When the cleaning is completed, the control valve is closed, the motor stops rotating, the system returns to its initial state, and the next filtration process begins. The interior of the filter housing is mainly composed of coarse filter screen, fine filter screen, suction pipe, stainless steel brush or stainless steel suction nozzle, sealing ring, anti-corrosion coating, rotating shaft, etc.

Wilkerson Filter M08 Series Wilkerson Agent

A simple filter is formed by dividing the container into upper and lower chambers using filter media. The suspension is added to the upper chamber, and under pressure, it enters the lower chamber through the filter medium to become the filtrate. Solid particles are trapped on the surface of the filter medium to form filter residue (or filter cake). During the filtration process, the surface area of the filter medium gradually thickens, and the resistance of the liquid passing through the filter residue layer increases, resulting in a decrease in filtration speed. When the filter chamber is filled with filter residue or the filtration speed is too low, stop filtering, remove the filter residue, and regenerate the filter medium to complete one filtration cycle. The liquid must overcome resistance when passing through the filter residue layer and filter medium, so there must be a pressure difference on both sides of the filter medium, which is the driving force for achieving filtration. Increasing the pressure difference can accelerate filtration, but particles that deform under pressure are prone to clogging the pores of the filtration medium under large pressure differences, resulting in slower filtration.

BERNSTEIN switch 602.1800.408

IFM proximity switch IG1208 with accessories, diameter 18mm, two wires

IFM proximity switch II5491

Hequan Relay RU2S-D24

Schneider switch XB2BD53C

Schneider switch XB4BW31B5

Hedeke pressure sensor HDA 4745-A-016-000

Beswick rotary joint M5CBL-1018-1-303

ASCO solenoid valve VCEFCMG551H401MO 24VDC

Beijiafu encoder EVM58N-011PNROBN-1213+coupling 9401 10 * 10

HANSEN solenoid valve HS7/3

BURKERT solenoid valve 00053882

KUBLER encoder 8.5823.3832.1024

KUBLER encoder 8.5020.0040.1024.S110.0015

Turck proximity switch FCS-G1/2A4-NA

ATOS Proportional Overflow Valve Coil Control Board E-MI-AC-01F20/2

TKC limit switch APL-410N

Beijiafu encoder EVM58N-011PNROBN-1213+coupling 9401 10 * 10

Parker gear pump 3339111657

KUEBLER encoder shaft sleeve 8.0010.4016.0000

HADOR Magnetic Level Gauge P10-G-S-920MM-A1

ASCO solenoid valve EF8320G174 24VDC

Hedeke pressure sensor EDS1791-N-400-000

ASCO solenoid valve VCEFCMG551H401MO 24VDC

Beswick rotary joint M5CBL-1018-1-303

ATOS installation bracket E-K-32M

Bonner sensor S18SN6R

Otonex proximity switch PR18-5DP