RU2021121306A - SYSTEM AND METHOD FOR PROCESSING FLAT OBJECTS - Google Patents

Claims (33)

1. System (100) for processing flat objects (102, 102a-e) having a first main surface and a second main surface opposite to it, moreover, flat objects (102, 102a-e) contain pressed mineral fiber material, while the system ( 100) contains: a conveyor (108) configured to sequentially move flat objects (102, 102a-e) one after the other through several stations (110, 110x, 112, 112x, 114, 116) in the direction (CD) of the conveyor movement, and these several stations (110, 110x, 112, 112x, 114, 116) include at least: a thickness measurement station (110, 110x) configured to determine a thickness-related property inherent in each of the flat objects (102, 102a-e) transported through the thickness measurement station (110, 110x), a sound measuring station (112, 112x) configured to determine the property associated with sound absorption and inherent in each of the flat objects (102, 102a-e) transported through the sound measuring station (112, 112x), moreover, the sound measuring station (112, 112x) contains a sound-reflecting surface (120) configured to support the first main surface of each flat object (102, 102a-e) transported through the sound measuring station (112, 112x), a sound emitter (122) configured to emit sound towards the sound-reflecting surface (120), a sound receiver (124) configured to receive sound reflected from the sound reflective surface (120), and a transducer (126) configured to determine a property related to sound absorption based on radiated and reflected sound, and a sorting station (116) configured to sort flat objects (102, 102a-e) into a plurality of fractions (116a-d, 116w) based on the respective defined properties of these objects. 2. The system (100) of claim 1, wherein the thickness measurement station (110, 110x) comprises a camera-based thickness measurement system (118) configured to determine a thickness related property inherent in each of the planar objects (102 , 102a-e). 3. The system (100) of claim 1, wherein the thickness measuring station (110, 110x) comprises a laser thickness gauge configured to determine a thickness-related property inherent in each of the planar objects (102, 102a-e). 4. System (100) according to any one of the preceding claims, wherein the sound receiver (124) of the sound measuring station (112, 112x) is configured to measure particle velocity and sound pressure of received sound. 5. System (100) according to any of the previous claims, in which the conveyor (108) is configured to continuously move flat objects (102, 102a-e) one after the other through several stations (110, 110x, 112, 112x, 114, 116 ). 6. System (100) according to any one of paragraphs. 1-4, in which the conveyor (108) is configured to intermittently move flat objects (102, 102a-e) one after the other through several stations (110, 110x, 112, 112x, 114, 116). 7. System (100) according to any one of the preceding claims, wherein the conveyor (108) is configured to transport flat objects (102, 102a-e) in a standing or lying position. 8. The system (100) according to any one of the preceding claims, further comprising a length measuring station (114) configured to determine a length-related property inherent in each of the flat objects (102, 102a-e) transported through the station (114) length measurements. 9. The system (100) according to any one of the preceding claims, further comprising a width measurement station (114) configured to determine a width-related property inherent in each of the flat objects (102, 102a-e) transported through the station (114) width measurements. 10. The system (100) according to any one of the preceding claims, further comprising a weight measurement station (114) configured to determine a weight-related property inherent in each of the flat objects (102, 102a-e) transported through the station (114) weight measurements. 11. The system (100) according to any of the preceding claims, further comprising a fiber type measuring station (114) configured to determine a property associated with the fiber type and inherent in each of the flat objects (102, 102a-e) transported through the station ( 114) fiber type measurements. 12. The system (100) according to any of the previous claims, further comprising a station (114) for measuring the type of binder, configured to determine the property associated with the type of binder and inherent in each of the flat objects (102, 102a-e) transported through the station ( 114) measuring the type of binder. 13. The system (100) according to any of the preceding claims, further comprising a surface layer detection station (114), configured to determine a property associated with the presence of a surface layer and inherent in each of the flat objects (102, 102a-e) transported through the station (114) surface layer detection. 14. The system (100) according to any of the preceding claims, further comprising a station (114) for measuring the level of humidity, configured to determine the property associated with the level of humidity and inherent in each of the flat objects (102, 102a-e) transported through the station ( 114) measuring the level of humidity. 15. A method (200) for processing flat objects (102, 102a-e) having a first main surface and a second main surface opposite to it, the flat objects (102, 102a-e) containing pressed mineral fiber material, wherein the method (200 ) contains: sequential movement (202) of flat objects (102, 102a-e) one after another through several stations (110, 110x, 112, 112x, 114, 116) in the direction (CD) of the conveyor movement to determine a number of properties, determination (204) of a property related to the thickness and inherent in each of the flat objects (102, 102a-e), using the station (110, 110x) measuring the thickness while transporting each of the flat objects (102, 102a-e) through the station (110 , 110x) thickness measurements, determination (206) of the sound absorption property inherent in each of the flat objects (102, 102a-e) using the sound measuring station (112, 112x) while transporting each of the flat objects (102, 102a-e) through the sound measuring station (112 , 112x), while the definition of the property associated with sound absorption, contains; supporting (206a) the first main surface of a flat object (102, 102a-e) transported through the sound measuring station (112, 112x) on a sound-reflecting surface (120), emitting (206b) sound towards the sound-reflecting surface (120) so that the emitted sound enters the flat object (102, 102a-e) on the second main surface and propagates through the flat object (102, 102a-e) towards the sound-reflecting surface (120) , receiving (206 s) the sound emerging from the second main surface of the flat object (102, 102a-e) and reflected by the sound-reflecting surface (120), and determining (206d) a property related to sound absorption based on emitted and received sound, and sorting (208) flat objects (102, 102a-e) into a plurality of fractions (116a-d, 116w) based on respectively determined properties of these objects using a marshalling yard (116), wherein at least one of the plurality of fractions (116a-d , 116w) was used to collect flat objects (102, 102a-e) containing pressed mineral fiber material. 16. The method (200) of claim 15, further comprising determining at least one of the following properties: a length property, a width property, a fiber type property, a binder type property, associated with the presence of a surface layer, and a property associated with the level of humidity, while at least one specific property is inherent in each of the flat objects (102, 102a-e).