Scaffolding is a common construction equipment, which provides workers with access and a platform for high-altitude tasks. Each unit comprises uprights, footboards, and cross braces, with a handrail-first approach necessitating the installation of handrails during scaffolding erection process. During the process of inspecting the scaffolding's integrity, it is necessary to ensure that the components are installed in the correct positions. However, workers often remove components to facilitate their tasks, which can potentially cause the scaffolding structure to become unstable or create gaps that are prone to falling. Additionally, during the scaffolding construction process, workers may neglect to install handrails for the sake of convenience. Currently, safety inspections on construction sites rely heavily on manual checks, which are time-consuming and labor-intensive and fail to instantly capture the details of scaffold unit components or the completeness of the installation process. This study proposes an integrated approach combining Graph Neural Network (GNN), keypoint detection, and computer vision to inspect the integrity and assembly order of scaffolding, aiding in the automation of inspection processes. Initially, Image Segmentation identifies upright, handrail and footboard positions. A multimodal model then combines deep learning keypoint detection, computer vision and depth estimation features to verify cross brace integrity. GNN analyze component spatial relationships to ensure standard compliance. Finally, a logic assessment that aligns with scaffolding construction regulations in Taiwan is designed to confirm whether the handrails-first assembly process and results present any fall hazards. Tested on real sites, the method successfully identified incomplete units and checked assembly compliance. Image segmentation for footboards, uprights and handrails showed accuracies of 96.2%, 90.6% and 86.7%, respectively. Keypoint accuracy for cross brace detection reached 97.8%. GNN validation was 85.2%, proving the method's effectiveness in identifying scaffolding integrity and erection safety.