In recent years, dredging projects in rivers and lakes have generated large volumes of sludge that exhibit high water content and low permeability. This dredged sludge needs to be treated quickly to reduce its volume, thus reducing transportation costs and environmental impacts. Flocculation combined with electroosmotic vacuum preloading is a new technology for dewatering sludge. At present, the influence of flocculants on the electrokinetic properties of sludge has not been thoroughly studied, and composite forms of these have not been applied in electroosmotic vacuum precompression. Therefore, inorganic flocculant and organic flocculant were combined to form a composite flocculant, which was used in electroosmosis vacuum preloading to increase the water discharge effect of dredged sludge. Based on analyzing the mechanism of flocculants, two kinds of composite flocculants, PAC-APAM and FeCl3-APAM, were configured, and the optimal ratio of inorganic flocculant and organic flocculant in the composite flocculant was determined with a settling column test. The properties, including pore size distribution, electric conductivity, and electroosmotic permeability coefficient, of the sludge mixed with flocculants PAC, FeCl3, APAM, PAC-APAM, and FeCl3-APAM were analyzed by NMR tests and Miler Soil Box tests. In addition, a model test of electroosmotic vacuum preloading treatment of dredged sludge was conducted, and the influences of different types of flocculants on the surface settlement, water discharge, current, pore water pressure, and shear strength of the sludge were compared and analyzed. The results showed that the composite flocculants suggested in this study were able to increase the electroosmotic permeability coefficient of sludge more significantly than single-type flocculants. In situations where electroosmotic vacuum preloading combined with composite flocculants was used to treat sludge, water discharge, and consolidation settlement were larger, and the shear strength of the treated sludge was higher. Compared with FeCl3-APAM, PAC-APAM showed better performance in electroosmotic vacuum preloading.

During the construction of pile foundations, the generation of vast amounts of engineering slurry, with poor geotechnical mechanical properties, requires expeditious treatment. In this paper, composite flocculants, consisting of anionic polyacrylamide (APAM), slaked lime (Ca (OH)2), and poly aluminum chloride (PAC) in varying proportions, were used to pretreat high water content (150%) engineering slurries. Afterwards, electroosmosissolidification treatment tests were carried out on the pretreated slurries to determine the influence of composite flocculant pretreatment on the efficacy of electro-osmosis treatment. The results indicate that the addition of a composite flocculant, APAM-PAC-Ca (OH)2, allows for the formation of flocs with structural pores within the slurry, which creates more favorable conditions for electroosmotic drainage treatment. After electroosmosis, the composite flocculant treated slurry led to lower average corrosion coefficients and presented with more uniform changes to soil moisture and 50% higher undrained soil shear strengths compared to samples treated with a single flocculant. The incorporation of Ca (OH)2 in the composite flocculant was shown to effectively decrease the extent of anode corrosion. Additionally, scanning electron microscope (SEM) imaging of the composite flocculant-treated and electroosmosis-treated slurries show the presence of CSH, CAH, AFt, polymer network structures and other products in the solidified slurry. The filling of the pores demonstrated the strengthening of the soil, meeting the requirements of external transportation and reuse.