To deal with the problem of receiving-end AC fault ride-through of an MMC-HVDC system connecting offshore wind power, coordinated suppression strategies of DC overvoltage are proposed to achieve the receiving-end AC fault ride-through. For a monopolar DC overvoltage, by reasonably switching the control mode of a bipolar MMC, the fault pole MMC can actively maintain DC voltage stability. The precise load-shedding control strategy of a wind farm is designed to ensure the full load operation of a non-fault pole MMC, so as to reduce the impact of monopolar MMC outage on the receiving-end system. For the bipolar DC overvoltage, a wind farm load-shedding control strategy based on local DC voltage measurement information is designed. This can actively reduce the output power of the wind farm according to the DC voltage change rate and deviation, and effectively suppress the rise rate and amplitude of DC voltage. Then additional pitch angle control and its parameter selection principle are proposed to make the wind farm and the capacitors in each converter station jointly maintain the stability of DC voltage, so as to improve the fault ride-through capability of the system. Finally, based on the RTLAB OP5600 real-time digital simulation platform, the system simulation model is built. The simulation results under different receiving-end AC faults show that the proposed coordinated suppression strategies of DC overvoltage can effectively ensure the DC voltage remains in a safe operational range, and maintains the safe and stable operation of the system. This work is supported by the Joint Funds of the National Natural Science Foundation of China (No. U2066208).