This paper presents experiments showing the existence of a critical filtered volume (CFV) when operating colloid dead-end filtration. The CFV is here defined as the filtered volume below which there is no irreversible (with respect to a break in the filtration) fouling on the membrane surface: it has thus the same meaning as cross-flow critical flux but applied to a dead-end process. The existence of the CFV is demonstrated when filtering stable latex or clay suspensions in constant-flux filtration experiments with alternating rinses: in contradiction to the current view, an irreversible deposit is not formed as soon as dead-end filtration begins. This critical filtered volume is shown to be dependent on the suspension stability and to be fully linked to the permeate flux: for permeate fluxes of 80 and 110 l h −1 m −2 the CFV is, respectively, 82 and 65 l m −2 for latex particles. Analyses of results are made by depicting the transition between concentration polarisation and deposit formation considering a critical osmotic pressure, which appears to be a characteristic of the fouling potential of a suspension. The results are discussed in the light of how this concept could lead to an interesting way to control and develop a strategy to operate filtration in dead-end mode.
SYNOPSISExperimental results on plasma treatments of polysulfone and polyetherimide to improve the wettability of these polymers are presented. The plasma is characterized by optical emission spectroscopy. The wettability of the polymer surfaces were checked by contact angle measurements and ESCA is used to compare the surfaces before and after plasma treatment. Correlations between contact angle, concentration of oxygen at the surface, and optical emission intensity of the OH radical have been established. Optimization of operational plasma parameters leading to the best wettability of the treated samples is reported. I NTRO D U CTlO NIn many technical applications, the desired surface and volume properties are not the same. Hence, it becomes difficult for a single material to fit both surface and volume requirements. At least for this reason, surface treatment and surface modification of polymeric materials is a domain of growing interest. Purely chemical, ' purely physical, and combined physical and ~h e m i c a l~'~ processes have been used to modify the surface of a polymer. In the last group, plasma techniques seem to be very powerful because it is a low-temperature treatment, applicable to a large variety of materials, and able to change the surface properties to a large extent (e.g., from wettability to impermeabilisation ) . 5 The main drawbacks of this technique are:1. The transfer from a small experimental setup to a large reactor fitting the real size and geometry of the items considered is not a simple homothetie. 2. A good understanding of the interactions between plasma species and treated surfaces, necessary to have a good control on the plasma parameters, is often very difficult to achieve.This article deals with the latter aspect. It is an attempt to establish relationships between three sets of parameters: ( 1 ) macroscopic parameters of the plasma (pressure, power, geometrical parameters) ; ( 2 ) composition of the gas phase with particular attention to the species responsible for surface modifications; and ( 3 ) composition and properties of the surface after plasma treatments.The first set of parameters is experimentally fixed during the plasma treatment. The plasma gas phase composition was checked by optical emission spectroscopy; the changes in surface composition were controlled by ESCA measurements. The surface wettability was evaluated by contact angle method, while the hydrophilic properties were determined by Hamilton's method.6From a technological point of view, the aim of this work is to show how a plasma process has been optimized to give the best wettability of two polymers-polysulfone ( PS ) and polyetherimide (PEI) -which are of great interest to make ultrafiltration and microfiltration membranes. Of course, in this case, wettability is one of the most important surface properties for these polymers.
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