Macroscopically sized supraparticles (SPs) are emerging as cutting-edge materials for industrial applications because of their unique properties unachievable for their nano-building blocks, but their effective methods are lacking. Here, a conceptually novel strategy is developed to assemble binary or ternary nanoparticles (NPs) within compartments of droplets through electrostatic interactions, making it possible to facilely fabricate millimeter-sized multicomponent ionic supraparticles (ISPs). The assembled ISPs possess unexpectedly high mechanical strength (50 N per bead), being amenable to practical applications. The key factors governing the assembly behavior of nano-building blocks within water droplet compartments are identified through regulating the size and charge density of NPs or ionic strength, providing key insights into the multileveled assembly of NPs beyond the conventional assembly. The strategy is demonstrated to be versatile since a library of tailor-made ISPs containing multicomponent, diversely shaped, and differently sized NPs can be facilely fabricated. As proof of this concept, it is showcased that this method enables the preparation of spatially orthogonal cascade catalysts by co-assembling acidic, basic, and metal sites in single millimeter-scaled particles. The catalysts exhibit significantly enhanced catalytic efficiency in a one-pot cascade synthesis of α-alkylated nitriles and high operational stability (200 h) in industrially preferred fixed-bed reactors.