Obtaining powered linear movement over a long range of motion is a common yet challenging task, as the majority of linear actuators have limited ranges of motion as determined by their functioning mechanisms. In this paper, the authors present a novel belt-based self-actuated linear drive (B-SALD), in which a self-powered moving platform slides on a slotted track with essentially unlimited range of motion (only limited by the length of the track). Unlike the traditional rack-and-pinion mechanism, the B-SALD system uses a double-sided timing belt as the power-transmitting element. With the teeth on its inner surface, the belt interacts with a timing pulley for its own circulation; with the teeth on its outer surface, the belt interacts with a linear rail with parallel slots and drives the translation of the moving platform. The unique functioning mechanism generates multiple distinct advantages: no lubrication is required; the slotted track is simple and inexpensive to manufacture; and it provides an inherent compliance to buffer shock loading. With the experiments conducted on a preliminary prototype, it has been demonstrated that the B-SALD is able to provide accurate positioning and continuous motion control, an overall mechanical efficiency of 70% over the majority of the load range, and the capability of generating large force output in the desired manner.
Abstract For most older adults, their own homes is the overwhelmingly preferred environment for living and growing older. However, for those living in homes with stairs, the difficulty and risk of injury in stair ascent/descent is a major challenge in their daily life, which may endanger the feasibility of such choice. In this paper, the authors present a novel assistive device, namely RailBot, to help mobility-challenged individuals (including frail older adults) to climb stairs more easily. Unlike the traditional elevators and stair lifts, the RailBot is a highly compact device that can be easily installed in existing stairways, allowing it to benefit a large number of individuals living in homes with stairs. Further, by assisting the users' stair climbing instead of carrying them upstairs, the RailBot enables and encourages the users to maintain and enhance their stair-climbing capabilities, and thus contributes to their long-term physical health. The design details of the RailBot prototype are presented, including the system configuration, the actuation mechanism of the mobile platform, as well as the intuitive control interface for start-stop control and speed regulation. After mounting the prototype in a real-world use environment, a small-scale human study was conducted, with the results clearly demonstrating the effectiveness of the RailBot assistance through the significant reduction of lower-limb muscle activities.
