The signal-to-noise ratio (SNR) is the key factor while magnetic resonance imaging (MRI) towards high spatial and temporal resolution. Compared with copper, the high temperature superconducting (HTS) coil has been proposed as a promising technique for SNR improvement in MRI. However, the HTS coil is not fully demonstrated its capability such as using HTS coil array to enlarge field-of-view. Hence, this study aimed to implement a 2-channel HTS coil array platform for small animal imaging at 7T MRI. First, the electromagnetic model of HTS coil array was built to simulate the SNR gain and B1 field homogeneity. Second, the 2-channel HTS coil array was implemented with minimized coupling effect. In the meanwhile, the Dewar for this coil configuration was fabricated to maintain the HTS coil array at low temperature of 77K. Third, the capability and feasibility of the homemade HTS coil array was verified by phantom and in-vivo rat body MR experiments. Finally, this HTS coil array platform was applied to the diffusion tensor imaging (DTI) of rat spine. In the theoretical and simulation results, the SNR gain of using 2-channel HTS coil array was approximate 2.2-time to the conventional copper coil array in the same configuration. Our experimental results show the HTS coil array at 7T MRI can provide a 1.9-time SNR gain in both of phantom and in-vivo rat spine scans while compared to copper coil array. In DTI experiment, the standard deviation of the deviation angle was dramatically reduced from 26.7-degree (by 2-channel copper coil array) to 18.9-degree (by 2-channel HTS coil array). In the future, the study will be potentially useful to facilitate the basic research of neuroscience and clinic diagnosis by the advantages of high SNR and larger field-of-view (FOV) of HTS phased array.