Through-Silicon Vias (TSV) based 3D Stacked IC (3D-SIC) technology introduces new design opportunities for wide operand width addition units. Different from state of the art direct folding proposals we introduce two cost-effective 3D Stacked Hybrid Adders with identical tier structure, which potentially makes the manufacturing of hardware wide-operand fast adders a reality. An $N$<alternatives> <inline-graphic xlink:href="voicu-ieq1-2598290.gif"/></alternatives>-bit adder implemented on a $K$<alternatives> <inline-graphic xlink:href="voicu-ieq2-2598290.gif"/></alternatives> identical tier stacked IC performs in parallel two $N/K$<alternatives> <inline-graphic xlink:href="voicu-ieq3-2598290.gif"/></alternatives>-bit additions on each tier according to the anticipated computation principle. Inter-tier carry signals performing the appropriate sum selection are propagated by TSVs. The practical implications of direct folding and of our hybrid carry-select/prefix approaches are evaluated by a thorough case study on 65 nm CMOS 3D adder implementations, for operand sizes up to 4,096 bits and 16 tiers. Our simulations indicate that in almost all configurations at least one of the two proposed 3D stacked hybrid approaches is faster than the fastest 3D folding approach. When considering an appropriate metric for 3D designs, i.e., the delay-footprint-heterogeneity product, the hybrid adders substantially outperform the folding counterparts by a factor in-between $1.67\times$<alternatives> <inline-graphic xlink:href="voicu-ieq4-2598290.gif"/></alternatives> and $23.95\times$<alternatives><inline-graphic xlink:href="voicu-ieq5-2598290.gif"/> </alternatives>.