Cavity magnomechanics, as an analogy of cavity optomechanics and cavity optomagnonics, offers a powerful platform to study coherent phonon-magnon interaction. Recently, phonon-magnon coupling in a ferromagnetic thin film integrated into a surface acoustic wave (SAW) resonator was experimentally demonstrated. This “on-chip SAW cavity” is a promising technology for future quantum circuit implementation of phonon-magnon interaction. For efficient quantum information processing, the phonon-magnon coupling constant needs to be enhanced by engineering not only ferromagnetic materials but also the film structures. In this work, we investigate phonon-magnon coupling in a tri-layer synthetic antiferromagnet (SAF) composed of a non-magnetic layer sandwiched by two ferromagnetic layers using a SAW cavity. The ferromagnetic layers antiferromagnetically couple because of an interlayer exchange interaction. We use a tri-layer CoFeB/Ru/CoFeB SAF, where SAW-spin wave conversion was recently reported.