The calculation of the height of fractured water-conducting zone (FWCZ) is of great significance for mine optimization design, water disaster prevention and safety production of the coal mines. In this paper, a height-prediction model of FWCZ based on extreme learning machine (ELM) is proposed. Aiming at its disadvantages of low prediction accuracy and relatively difficult parameter optimization, the ELM prediction model is optimized by the grey-wolf optimization algorithm (GOA), whale optimization algorithm (WOA) and salp optimization algorithm (SOA) respectively. These optimization algorithms overcome the problems of slow convergence, poor stability, and tendency to fall into local optimality of traditional neural networks. The mining depth, mining height, overburden strata structure, working face length and coal seam dip angle are selected as the main controlling factors for the height of FWCZ. A total of 42 fields measured samples are collected and divided into two subsets for training and validating with a ratio of 36/6. The prediction capability of GOA-ELM, WOA-ELM and SOA-ELM models are evaluated and compared, and the results show that the calculation results of the three models are optimized compared with the ELM model. The prediction capability of GOA and WOA are similar, while the prediction results of SOA-ELM are better than the other two models, and the relative errors of the test sets are all less than 10%. Therefore, the SOA-ELM model is finally applied to predict the height of FWCZ formed after the mining of No.15 coal seam in Xinjian Coal Mine. Finally, prediction results are verified by the measured data of the borehole television detection instrument, which shows good consistency. It further proves the effectiveness of the swarm intelligence optimization algorithm in the prediction of the height of FWCZ.