Pipeline magnetic separators MSP-MC

Pipeline magnetic grate separator MSP-MC is designed to separate iron contamination from liquids (or dry substances of good bulk properties).

Design of flow-liquid separator

The basic elements the magnetic grate separator in housing consists of are magnetic tubes (made from stainless steel). While the material flows around the magnetic tubes, a very strong magnetic field (generated by the neodymium NdFeB magnets inside of the tubes) traps all metallic particles on the surface of the tubes. The sets of tubes are placed one above the other inside of the housing (or one behind the other – in case of a vertical position of the tubes) and the first set of tubes consists of one tube less. The grate sieve - created in this way – is in a very intensive contact with the flowing material and can capture even the smallest ferromagnetic impurities and guarantees an extremely high separation efficiency.

How does flow-liquid magnetic separator work?

The metal particles captured on the magnetic tubes migrate to the rear of the tubes where they remain protected from wash-off until the tubes are cleaned. Our pipeline magnetic separator is easy to install and maintain, made from stainless steel and its robust design (in connection with very strong neo magnets from rare earth ores) provides for a long-term and durable solution to magnetic separation problems.

Which way is flow-liquid separator cleaned?

In the course of manual cleaning the inner part of the separator is taken out, the magnetic cores are pulled out of the tubes (by operating lever) and the captured magnetic impurities fall off the tubes spontaneously. In case of bigger pipeline magnetic separators (or if the cleaned material is considerably contaminated with ferromagnetic impurities), the demagnetization process can be carried out pneumatically (and – if needed - with automatic control).

Other advantages of our standard magnetic separator for pressure pipeline transport MSP-MC

a peephole (for the optical inspection of the magnetic tubes as well as of the material flow)
an integrated lock of the magnetic tubes (preventing unauthorized persons from tampering with the separator)
a chambered system ensuring the exposion of the liquid to extremely strong magnetic field for maximum time (the best possible efficiency of the magnetic separation is achieved as the entire length of the magnetic tubes is utilized)
a mesh strainer (removing non-magnetic particles)

Max. magnetic induction: up to 18 700 Gauss on the magnetic core and up to 12 200 Gauss on the surface of the protective tubes (with a tolerance of +/- 10%).

Which industrial branches can the flow-liquid magnetic separator be use of in?

The pipeline magnetic separator finds use in food, chemical and ceramic industries as well as in sanitary facilities.

Strojírenský a slévárenský průmysl

Tepelné elektrárny

Keramický a sklářský průmysl

Chemický průmysl, nátěrové hmoty

Automobilový průmysl

Potravinářský průmysl

Plastikářský a gumárernský průmysl

Papírenský průmysl

Sanitární provozy

Detailed description

What pipeline is the separtor connected to?

In order to ensure a quick and easy connection to the pipeline, the separator housing is standardly manufactured in diameters from 50 to 250 mm (but we can adjust the connection type as well as its size to client's requirements).

Model family

MSP-MC

The jacketed filters are used in heated pipeline applications where the temperature is critical to the viscosity (i. e., the separator tempering prevents the cleaned s - such as chocolate, syrups, jams, sauces - from solidifying).

DETAIL

Product	Flow rate (l/m) Maximum capacity depends on the type and properties of the material being cleaned	Connecting diameter (mm)	Datasheet (CZ)
MSP-MC 50 N	500	20	display PDF
MSP-MC 100 N	1100	100	display PDF
MSP-MC 150 N	6500	150	display PDF
MSP-MC 200 N	6800	200	display PDF
MSP-MC 250 N	6900	250	display PDF

MSP-MC EKO

This economical version of the pipeline magnetic separator with manual cleaning is designed for the separation of ferromagnetic particles from liquids flowing in small diameter pipes (as the separator body includes only one magnetic tube in a stainless steel housing).

DETAIL

Just like in the case of the standard MSP-MC, the trapped magnetic particles remain at the rear of the magnetic tube, i. e., they do not block the flowing cleaned material and are protected from wash-off until the protective tube is cleaned. During the cleaning it is necessary to unscrew the union nut in order to release the separator body from the piping system. Afterwards the magnetic core is moved by the control lever to the upper position, enabling the trapped magnetic impurities to spontaneously fall off the surface of the protective stainless steel tube (if needed, the protective tube can be also washed with water).

Product	Connecting diameter (in inches)	Datasheet (CZ)
MSP-MC EKO 1/2 N	1/2"	display PDF
MSP-MC EKO 3/4 N	3/4"	display PDF
MSP-MC EKO 1 N	1"	display PDF
MSP-MC EKO 1 1/4 N	1 1/4"	display PDF

MSP-SC

The MSP-SC is a semi-automatic version of the standard MSP-MC pipeline magnetic separator.

DETAIL

Semi-automatic pipeline magnetic separator MSP-SC

The separator MSP-SC is equipped with

flaps controlling the material in-/outflow
valves controlling the rinse water inflow and the outflow of ferrous contaminants
a FESTO pneumatic cylinder (to pull out the magnetic cores during the separator cleaning)

Although the working principle does not differ from that of the manual version, the cleaning itself is much simpler.

Main pros of the semi-automatic version:

the cleaning of the separator does not require taking the separator body out of the piping system.
thanks to the pneumatically controlled cylinder the handling of magnetic cores is much easier (in particular in case of bigger separators or extremely contaminated materials).

During the cleaning process the inflow as well as the outflow of the material must be manually stopped (by shutting the corresponding flaps). The manually controlled pneumatic cylinder will push the magnetic cores out of the protective stainless steel tubes into the upper position. Afterwards, the ball valves of the rinse and discharge pipes are manually opened, so that the ferromagnetic particles rinsed off of the protective stainless steel tubes can flow away through the waste hole (situated at the bottom of the separator body). In conclusion, both the ball valves are to be closed and the magnet cores moved to the bottom (working) position. The material inlet and outlet will be opened and the process of magnetic separation will continue until the next cleaning.