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Cerebral palsy manifests itself in the first years of a child's life and may be caused by brain injuries, or abnormal brain development, reflecting in disorders in the child's motor capacity, each case varying in terms of severity and type of motor disorders. The average life expectancy of these children has been increasing, which means that it is relevant to find alternatives to improve the quality of life of those affected by this condition. Thus, the HomeHoist project emerged, which aimed to function as a single device for transferring patients with cerebral palsy without burdening the caregiver. The HomeHoist device consisted of an electric wheelchair, with a built-in hoist, removable seat, and free interior space, which allowed the patient to be transferred between various surfaces, such as beds and toilets. Following an internship at the company Orthos XXI, the interest arose to revive this project, which had been concluded in 2014. The aspects identified for improving the device were to incorporate verticalization; include leg raising, which despite being a goal in the original project, was not achieved; split the seat and backrest to customize the operation of the device; free up the lateral space on the seat to facilitate patient handling; and change the structure and components to meet the company's production, reducing production time and cost. Using project methodologies such as the goal tree, analysis of functions, and the method of weighted goals, it was possible, among several solutions, to understand which ones best fit the intended goals, followed by the determination of dimensional constraints and the selection and placement of mechanical components, to obtain a 3D model of the final device. With the model it was possible to obtain 65º verticalization; 155º reclination; the dimensions of the device were as intended; and the foot elevation was incorporated, although it did not allow to completely stretch the legs. Then, a brief analysis of the electrical components to be incorporated was made, followed by the simulation of two components, and with the simulation of one of them, the arch, it was realised that it would have to be redesigned to withstand the load that was applied to it, by increasing the diameter of the tube and the positioning of the rings. Finally, with the production of the prototype, it was possible to understand what should be improved to facilitate the production of the device, both in terms of production and assembly. The functioning of the device was also tested, to confirm the information obtained with the 3D model.