High-entropy alloys (HEAs) are solid solutions that consist of multi-principal elements with near-equimolar ratios. Due to the diversity of constituent elements, atomic size difference leads to severe lattice distortion effect, which results in many special mechanical properties that are unique from traditional ones. At different temperatures, high-entropy alloys also exhibit excellent mechanical properties such as high strength, ductility, fracture toughness, high temperature stability and fatigue resistance. Among all this family, the refractory high-entropy alloy with BCC structure can maintain phase stability at high temperatures and has excellent softening resistance. Therefore, continuing our laboratory's previous research on the mechanical properties and deformation behavior of BCC low to high-entropy alloys at room temperature, in this research we conducted nanoindentation tests, micropillar compression test and TEM cross-section observation on grains with different crystallographic orientations from W, WTaMo and WTaMoNbV high-entropy alloys at different temperature to explore the effect of temperature on mechanical properties and deformation mechanism. Research shows that the elastic and plastic anisotropy of high-entropy alloys are smaller than traditional alloys at any temperature. Slip plane of high-entropy alloys and serrations of stress-strain curve are less obvious than traditional alloys, showing that high-entropy alloys tend to move in short-range dislocation slips. High-entropy alloys maintain the characteristics of high yield strength, which has better high-temperature softening resistance than traditional alloys.