Measurements of dust properties in galaxies across cosmic time can help put valuable constraints on galaxy formation theories. Recent studies have shown that at a fixed stellar mass, galaxies at cosmic noon (z ∼ 2) have about one order of magnitude higher dust mass than those in the local Universe, suggesting a drastic change in dust formation efficiency in the early Universe. However, these studies often lack sufficient depths in the critical far-infrared wavebands or key information such as gas-phase metallicity, leading to potentially biased results or inconclusive explanations. Based on a newly created super-deblended catalogue that includes the latest ultra-deep SCUBA-2 450 and 850 μm data, we select 41 main-sequence galaxies that are significantly detected in at least three far-infrared bands, and their spectroscopic redshifts and gas-phase metallicity measurements are available in the archival data of Keck/MOSFIRE and VLT/KMOS. Employing modified blackbody (MBB) spectral energy distribution (SED) fitting, dust masses and temperatures were determined. The sample was divided into three redshift bins (z=0.9, 1.5, and 2.4) to study evolutionary trends. Our results confirm that sources with higher stellar masses have higher dust masses, and a positive correlation exists between gas-phase metallicity and dust mass. Despite no statistically significant correlation between metallicity and the dust-to-stellar mass ratio (D/M∗), D/M∗ ratios in higher redshift samples are shown approximately 3.3 times larger than those at z ∼ 0. We also confirm that higher redshift galaxies have significantly higher dust masses at given stellar masses and metallicity. By inferring gas masses from the known correlations for the main sequence galaxies, we find that galaxies from local to z ∼ 2 all follow the same correlation between dust-to-gas ratios and metallicity. As a result, we attribute the significantly higher dust masses at higher redshifts to higher gas fractions.