This filtering sheet is specially made for Efficiency of cartridges which can separate impurities and particles in Frying oilTo select a proper filter system for the requirements of a given application, knowledge of filter efficiency and dirt capacity is required. The filter manufacturer needs to provide data, which are based on test procedures simulating real parameters on a laboratory scale. At present there is no standard for liquid filter testing (except multipass test to ISO 4572, which is for hydraulic filters).

This Efficiency of cartridges has 4 advantages:
.It can be used in a high temperature environment. There is no toughness decline after it is dipped into
200 frying oil for 15 days.
.It has a high interstice which is above 5 micron diameter by its labyrinth design so that the filtering sheet can purify the Frying oil.
.Its ventilation characteristic makes filtering sheet has high efficiency in filtration. Since the sticky oil can pass through the filtering sheet more easily, it has high filtration efficiency.
.It has high toughness. The filtering sheet can be used in high vacuum environment.

Early cartridge filters were constructed from a square weave S.S. mesh. In this case, every hole or pore is nominally the same size. This measurement can be accomplished by evaluation of wire counts and thickness or by direct observation under microscope. As filter developed, different weaves (Photograph of woven wire mesh) for the mesh is being used and now it is difficult to measure by count and thickness of wire. Consequently, a number of methods of establishing the particle removal rating were developed.

Glass beads suspension is passing through a test filter under defined test conditions, and then passing the filtered suspension through an analysis membrane. The analysis membrane was than observed, and the largest glass bead identified and measured. This measurement was taken as the absolute rating of the filter. So, the absolute rating of the filter was defined as the largest hard spherical particle, which would just pass through the filter.

To select a proper filter system for the requirements of a given application, knowledge of filter efficiency and dirt capacity is required. The filter manufacturer needs to provide data, which are based on test procedures simulating real parameters on a laboratory scale. At present there is no standard for liquid filter testing (except multipass test to ISO 4572, which is for hydraulic filters).

Early cartridge filters were constructed from a square weave S.S. mesh. In this case, every hole or pore is nominally the same size. This measurement can be accomplished by evaluation of wire counts and thickness or by direct observation under microscope. As filter developed, different weaves (Photograph of woven wire mesh) for the mesh is being used and now it is difficult to measure by count and thickness of wire. Consequently, a number of methods of establishing the particle removal rating were developed.
As described in ARP901 (Ref2), this is based on the observation that, if a circular hole in a flat plate is fully wetted in liquid, the minimum bubble radius that the hole will support is the radius of the hole. The differential pressure across the bubble under these conditions is controlled by the surface tension, so that

¶P = 2s Where ¶P = differential pressur
r s = Surface tension

Since the minimum bubble radius corresponds to the maximum differential pressure before bubbles are released from the hole, the measurement of differential pressure can be used to establish a size for the hole.
(Picture of bubble point test)

ARP901 extends the method to triangular holes in flat plates, but it must be recognized that the measured differential pressure is also dependent on the shape of the hole.

¶P = Ks s = surface tension
r r = pore size

Both the glass bead test and the bubble point test were historically reputed to provide an absolute rating for the filter media, but also implied that this was a cut-off point, in the sense that in service no particles below this size were removed, and all particles above this size were removed. Both methods were based on spherical particles, which only occur rarely in real filtration applications.

In an effort to address these difficulties, a further test was developed, and is also included in MIL-F-8815. This has been called the "nominal rating".

This Multipass Test is used for the evaluation of hydraulic filters. A test contaminant is added to hydraulic oil and re-circulated through the filter under test. Samples are taken from upstream and downstream of the filter for particle counting, and consequently efficiency evaluation. The amount of solids added can be used to determine the perceptible dirt capacity.

The test replicates the conditions a hydraulic filter would see of a re-circulating contaminant in a closed loop. For most filters used in the process industries this type of operation is not been applicable. Generally they are used for low viscosity fluids such as water, on a single-pass through the filters. The concern of the user is the quality of filtrate downstream of the filter after a single-pass, and the life on stream.