In this study, the multifunctional potential of conductive textile fibres based on natural bamboo metalized with chemical/electrochemical deposits and copper particles/layers was investigated. The synthesis was done in three steps: pre-treatment of nonconductive textiles; chemical deposition of Cu particles by the cyclic dipping method; and obtaining conductive bamboo fibres using the electroplating method. The Cu layer was electrodeposited galvanostatically on bamboo from the sulphate electrolytes without wetting agents. To tighten the textile bamboo cloth, a frame designed using 3D printing was used because immersing the textile in the electrolyte and during drying causes wrinkles and creases, which affect the non-uniform distribution of both conductive particles and the thickness of the copper metallization layer. Characterized by SEM and optical microscopy, the chemical and electrochemical depositions of Cu around the bamboo fibres were confirmed. The particles filled the micro spaces between the bamboo fibres and on the surface of the fibres and made the network. This network between nonconductive fibre-conductive nano particles and a conductive Cu layer contributes to increasing the electrical conductivity of the synthesized multifunctional composite. The electroplating of Cu in the form of a compact layer as shells contributed to the trapping of Cu particles on the bamboo fibres themselves, so they are not removed after washing.