Conventional　pressure-type　anchoring　systems　face　challenges　such　as　difficulty　in　recovery,　low　recovery　efficiency,　and　insufficient　durability　over　long-term　use.　Although　the　single-use　cost　of　Carbon　Fibre　Reinforced　Polymer　(CFRP)　strand　anchors　is　higher　than　that　of　conventional　steel　strands,　recovery　and　reuse　can　significantly　reduce　costs.　Therefore,　this　study　aims　to　investigate　the　bonded　anchoring　method　of　CFRP　and　proposes　an　innovative　thermoplastic　CFRP　prestressed　strand　design　that　combines　both　anchoring　strength　and　recoverability　to　address　the　shortcomings　of　existing　anchoring　systems.　Two　bonding　materials,　thermosetting　resin　and　thermoplastic　resin,　were　selected　for　bond　strength　tests　under　different　conditions.　The　results　indicated　that　epoxy　resin　had　a　bonding　force　of　280　kN　and　an　anchoring　efficiency　of　approximately　70%,　making　it　the　most　suitable　material.　However,　the　anchoring　efficiency　still　needs　improvement.　Based　on　this,　an　improved　design　scheme　was　proposed,　which　can　increase　anchoring　efficiency　to　over　95%.　Additionally,　based　on　the　dispersed　bonding　anchor　system,　this　study　explored　a　solution　that　involves　adding　a　positioning　plate　at　the　end　of　the　anchor　strand　and　using　epoxy　resin　for　anchoring.　The　anchoring　performance　tests　showed　that　the　tensile　strength　of　the　CFRP　strand　ranged　from　2.7-2.8　GPa,　with　an　average　anchoring　efficiency　of　100.5%,　demonstrating　excellent　anchoring　performance.　Further　thermoplastic　recovery　tests　showed　that　when　the　temperature　increased　to　90　degrees　C,　the　maximum　recovery　force　of　the　strand　was　17.2　kN,　about　4.4%　of　the　ultimate　load.　When　the　temperature　increased　to　150　degrees　C,　the　maximum　recovery　force　was　7.5　kN.　The　recovered　CFRP　strands　were　clean,　with　no　resin　residue,　and　had　no　damage,　maintaining　an　intact　structure.　The　proposed　thermoplastic　CFRP　prestressed　strand　design　demonstrates　significant　advantages　in　anchoring　strength　and　recoverability.　With　the　improved　design,　anchoring　efficiency　can　be　increased　to　over　95%,　and　the　high-temperature　recovery　process　shows　good　feasibility.　Compared　with　traditional　anchoring　systems,　CFRP　strands　offer　higher　anchoring　efficiency,　lower　recovery　force　requirements,　better　economics,　and　sustainability,　making　them　a　promising　solution　for　engineering　applications.