高絡み合いのポリマーネットワークの追加製造
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PubMedで要約を見る
まとめ
この要約は機械生成です。この研究は,光と暗のポリメリゼーションを使用して,高度に絡み合ったポリマーネットワークを作成するための新しい方法を導入しています. この技術により 3Dプリントされた材料の 硬さや頑丈性が向上し エネルギー吸収能力も向上します
科学分野
- 材料科学
- ポリマー化学
- アディティブ製造
背景
- 密度の高いポリマー鎖の絡み合いは 材料の硬さと強さを高めます
- バット光ポリメリゼーション添加物製造 (例えば,デジタル光処理) で高絡み密度を達成することは困難です.
- 現在の方法では 印刷後に熱や光にさらされるような刺激が必要になります
研究 の 目的
- 添加物製造過程で高度に絡み合ったポリマーネットワークを作成するための簡単な戦略を開発する.
- 機械性能が向上したハイドロゲルやエラストマーの製造を可能にします.
- 高解像度,マルチ素材の3Dプリントの汎用的なアプローチを示します.
主な方法
- 印刷過程で光と暗のポリメリゼーションを組み合わせた新しいアプローチです.
- 室温でVat光ポリメリゼーション添加物製造 (例えば,デジタル光処理)
- モノマー変換,絡み合いの密度,および機械的特性 (拡張エネルギー) の特徴.
主要な成果
- 印刷後の刺激なしに室温で高いモノマー変換を達成した.
- 伝統的なデジタル光処理と比較して4倍から7倍の拡張エネルギーを持つ高度に絡み合った水素と弾性物質を製造した.
- 湿った組織に プログラムされた粘着のような特徴を持つ 高解像度の多素材構造を 印刷しました
結論
- 開発されたライトとダークのポリメリゼーション戦略は,添加物製造中に密集したポリマーネットワークを効果的に作成します.
- この方法は,3Dプリントされた材料の機械性能 (硬さ,タフさ,エネルギー吸収) を大幅に改善します.
- このアプローチは,生物医学機器を含む様々な用途のための高度な機能的材料と複雑な構造を生産するために一般化できます.
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