The fine-grain process (FGP) has been developed to enhance the strength and creep performance of several superalloys at moderate temperature; however, studies on the casting ability of the TM-321 superalloy using the FGP remain scant. Therefore, in this study, the fine-grained TM-321 manufacturing process was assessed and improved. In the first part of the study, the casting parameters were controlled to produce two kind test bars each containing varying grain sizes; the tensile strength and creep properties of fine-grained TM-321 superalloy were subsequently evaluated. In the second part of the study, zirconium (Zr) was added to tailor the TM-321 superalloy, investigating the effects of Zr content on the mechanical properties and fracture modes of the test bars. The grain size of the fine-grained TM-321 superalloy was nearly 90 μm. The results of this study showed that the tensile strength and creep performance of the fine-grained TM-321 test bars all achieved the EMS-55447 specification. In addition, because the TM-321 superalloy contains a higher content of solid-solution strengthening elements W and Ta, and the higher Ta content inhibited the γ′ phase from coagulating and growing at high temperatures during long exposure and increased the thermal stability of the TM-321 superalloy. Moreover, superior to that of the M23C6 carbides of the Mar-M247 superalloy, the thermal stability of the M6C type carbide of the TM-321 superalloy helped improve its mechanical properties. Therefore, the creep life of the fine-grained TM-321 superalloy at 760oC/724 MPa (101 h) is 4.3 times longer than the specification value (23 h), which is also 6.2 times greater than conventionally casting test bars and 1.43 times longer than that of the Mar-M247 superalloy produced using the same manufacturing process. Concerning the influence of Zr content on the mechanical properties of fine-grained TM-321 superalloy at moderate temperature, the results showed that when the Zr content was increased from 0.08 wt% (TZ1) to 0.42 wt% (TZ3), the creep life of TZ3 alloy at 760oC/724 MPa was twice as long as that of the original TM-321 superalloy (TZ1). These results are attributed to the synergic effects of the following strengthening mechanisms: (1) the grain size of the TM-321 superalloy was refined by adding Zr; (2) the Zr addition increased the strength of the γ/γ′ microstructure; and (3) adding Zr refined the grain-boundary (GB) carbides. The fractographic observation of creep and tensile tests demonstrated that crack propagation along the GBs was reduced as the Zr content increased, whereas secondary cracks within the grain interior increased. The fracture modes of the fine-grained TM-321 superalloy were transformed from typical intergranular modes into transgranular and intergranular mixed modes by increasing the Zr content from 0.08 wt% to 0.42 wt%. As mentioned, this study confirmed that adding an appropriate amount of Zr improved the performance of fine-grained TM-321 superalloy and substantially improved its creep life, making the TM-321 superalloy an excellent choice as engine components operating at moderate temperature.