SMART is a low-latency solution that transmits nonconflicting flits to remote routers, enabling traversal of multi-hop paths within a single cycle. It reduces packet latency but ignores high power consumption in idle components. Additionally, SMART's low latency is highly dependent on HPCMax, which represents the maximum number of hops traversed within a cycle. Therefore, this paper presents SMART-PG, a power gating method based on SMART that reduces network power consumption by shutting down idle components such as router buffers under low-load conditions. We also extend the router architecture to enable the continuous establishment of single-cycle multi-hop bypass paths. Compared to SMART routers, our method eliminates packet buffering even when a packet reaches the last router of a single-cycle multi-hop path, reducing packet latency and sensitivity to HPCMax. Finally, we propose a routing algorithm that enables efficient packet transmission in one-dimensional and two-dimensional networks even when routers are powered off. Experimental results show that our method reduces packet latency and static power consumption by an average of 7.5% and 46.4%, respectively, compared to the baseline router. Compared to SMART routers, our method demonstrates significant superiority in terms of packet latency and the impact of multi-hop length on packet latency.