By analysing the light curves of the ZZ Ceti star we aim to determine its pulsational frequencies and to give constraints on the main stellar parameters using asteroseismology. We performed the Fourier analysis of the TESS light curves of and selected the possible pulsational modes. We also used spectroscopic data collected with the Cosmic Origins Spectrograph of the Hubble Space Telescope to give constraints for the asteroseismic analysis. We perform the latter with period-to-period fits using fully evolutionary white dwarf models. The star presented in this paper shows a particularly high number (41) of pulsational frequencies, which provides a potential opportunity for detailed asteroseismic investigations. We found a mean period spacing of ∼ 40. 5 seconds, which allows us to state that the stellar mass of WD 1310+583 is larger than ∼ 0. 57 M_⊙. We also attempted an asteroseismological analysis by performing period-to-period fits, but we were unable to find a single statistically significant asteroseismological solution. We adopted a tentative solution consisting of a white dwarf model with M_*=0. 632, M_⊙, ̊m eff = 11, 702, K, and an asteroseismic distance d = 27. 75^ +0. 17 _ -0. 15, pc, which is significantly smaller than the one predicted by Gaia (d = 30. 79± 0. 2, pc). We also determined that the rotational period of our target is 1. 18, d.
Bognár et al. (Mon,) studied this question.