Localized, irreversible adsorption of interacting colloid particles from well-defined hows was studied experimentally and theoretically. The impinging-jet cells were used for creating the axisymmetric and plane-parallel (slot) laminar flows, enabling a direct microscope determination of particle adsorption kinetics. Monodisperse suspension of polystyrene latex particles was used for measuring the influence of how intensity (shear rate) on particle adsorption kinetics. The experimental data were interpreted in terms of the approximate analytical predictions derived using the random sequential adsorption (RSA) approach valid for low and moderate surface concentrations. For an arbitrary range of surface concentrations the general sequential Brownian dynamics (SBD) simulation method was used to interpret the experimental data. It was found that these theoretical methods reflected well the characteristic features of the adsorption experiments, especially the significant decrease of adsorption kinetics for higher how shear rates and low ionic strengths caused by the hydrodynamic scattering effect (HSE). Due to this effect, the surface-blocking phenomena for spherical particles become analogous to elongated non-spherical particles under no-how adsorption conditions.