Differential fast scanning calorimetry (DFSC) has been combined with a novel differential reheating method (DRM). Interrupted quenching at different temperatures followed by overcritical cooling enables both time- and temperature-dependent investigations of precipitation reactions in aluminium alloys during cooling from solution annealing at cooling rates between 1K/s and 105K/s. Together with conventional differential scanning calorimetry (DSC) results, for the very first time, a full continuous cooling precipitation (CCP) diagram for a highly concentrated wrought AlZnMgCu alloy has been developed. For alloy AA7150, three precipitation reactions with their respective start and end temperatures were observed by DFSC. The critical cooling rate for suppressing the high-temperature precipitation of S-Al2CuMg was found to be ~10K/s, whereas for the medium-temperature precipitation of η-Mg(Zn,Al,Cu)2 it is ~100K/s and for the low-temperature precipitation of Y-phase plates enriched in Zn and Cu it is ~300K/s. The method can potentially be transferred to similar precipitate-forming metallic systems or related solid-state phase transformation systems also beyond the particular system analysed in the present study.