TEXTILE DETECTION MODULE, TEXTILE SORTING SYSTEM AND USING METHOD THEREOF

• Main Authors: YANG, Yi-Cyun, HSIAO, Kai-Jen, HUANG, Kuan-Yeh, HUANG, Ssu-Yu, JIANG, Ruei-Han, CHU, Jen-You
• Format: Patent
• Language: English; French; German
• Published: 04.05.2022
• Subjects: INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIRCHEMICAL OR PHYSICAL PROPERTIES; MEASURING; PERFORMING OPERATIONS; PHYSICS; POSTAL SORTING; SEPARATING SOLIDS FROM SOLIDS; SORTING; SORTING INDIVIDUAL ARTICLES, OR BULK MATERIAL FIT TO BE SORTEDPIECE-MEAL, e.g. BY PICKING; TESTING; TRANSPORTING

A textile detection module (100) is suitable for detecting a test specimen (20). The textile detection module (100) includes a height sensor (110), an excitation light source (120), an optical detector (130), and a focuser (140). The height sensor (110) is suitable for measuring a height of the test specimen (20) to generate a height signal (S1). The excitation light source (120) provides an excitation light beam (L1). The optical detector (130) is disposed on a transmission path of the excitation light beam (L1) and is suitable for receiving the excitation light beam (L1) and emitting the excitation light beam (L1) along the optical axis and receiving a detection light beam (L3) to generate a detection result. The focuser (140) is disposed on the transmission path of the excitation light beam (L1) emitted by the optical detector (130). The focuser (140) includes a focus lens (142) suitable for converting the excitation light beam (L1) into a focused excitation light beam (L2). The focused excitation light beam (L2) is transmitted from the focuser (140) to the test specimen (20) to generate the detection light beam (L3), wherein the focuser (140) adjusts a position of the focus lens (142) according to the height signal (S1). The height sensor (110) measures the height of the test specimen (20) at a first position (PI) of the conveying path (A), the optical detector (130) performs optical detection on the test specimen (20) at a second position (P2) of the conveying path (A), and the test specimen (20) moves from the first position (PI) to the second position (P2) along the conveying path (A).