Disclosed are an apparatus and a method for manufacturing a heat insulator, including: a frame having a feeder provided at front side of the frame for feeding a cross-linked foam polyethylene sheet and a winder provided at rear side of the frame for winding a completed heat insulator; a cutting part
Disclosed are an apparatus and a method for manufacturing a heat insulator, including: a frame having a feeder provided at front side of the frame for feeding a cross-linked foam polyethylene sheet and a winder provided at rear side of the frame for winding a completed heat insulator; a cutting part provided at a leading side of the frame, a widening part provided at a rear side of the cutting part, which is for transforming the cutoff slots into cells by widening a width of the cross-linked foam polyethylene sheet formed with the cutoff slots; a cooling part provided at a rear side of the widening part, which has cooling rollers to continuously maintain a widened width of the cross-linked foam polyethylene sheet and a shape of the cells transformed from the cutoff slots; and a sheet-attaching part provided at a rear side of the cooling part.
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1. An apparatus for manufacturing a heat insulator, the apparatus comprising: a frame having a feeder provided at front side of the frame for feeding a cross-linked foam polyethylene sheet and a winder provided at rear side of the frame for winding a completed heat insulator;a cutting part provided
1. An apparatus for manufacturing a heat insulator, the apparatus comprising: a frame having a feeder provided at front side of the frame for feeding a cross-linked foam polyethylene sheet and a winder provided at rear side of the frame for winding a completed heat insulator;a cutting part provided at a leading side of the frame, which is for forming multiple cutoff slots in the cross-linked foam polyethylene sheet fed from the feeder;a widening part provided at a rear side of the cutting part, which is for transforming the cutoff slots into cells by widening a width of the cross-linked foam polyethylene sheet formed with the cutoff slots;a cooling part provided at a rear side of the widening part, which has cooling rollers to continuously maintain a widened width of the cross-linked foam polyethylene sheet and a shape of the cells transformed from the cutoff slots; anda sheet-attaching part provided at a rear side of the cooling part, which is for attaching an aluminum film on at least one surface of the widened cross-linked foam polyethylene sheet formed with the cells so as to show high reflectivity and low emissivity. 2. The apparatus as claimed in claim 1, wherein the cutting part comprises: a cutting roller for forming the cutoff slots in the fed cross-linked foam polyethylene sheet; andupper/lower feeding rollers provided at a rear side of the cutting roller, which are for feeding the cross-linked foam polyethylene sheet formed with the cutoff slots, to the widening part,wherein the cutting roller comprises: a lower roller supported by the frame; and an upper roller positioned at an upper side of the lower roller, which has multiple blades for forming the cutoff slots,wherein the blades are formed at different positions from adjacent blades; and an angle of the blades is maintained at an angle of 60° or less with respect to a horizontal plane of the lower roller so as to make it easy to form the cutoff slots and to reduce wear. 3. The apparatus as claimed in claim 2, wherein the upper roller of the cutting roller, the upper feeding roller of the feeding roller, and the cooling roller and the heating roller, positioned at an upper side, correspond to a thickness of the fed cross-linked foam polyethylene sheet, by a height adjusting means. 4. The apparatus as claimed in claim 1, wherein the widening part comprises: a widening tunnel with a narrow inlet and a wide outlet, supported by the frame;a transfer means provided at both sides of the widening tunnel, which is for transferring the discharged cross-linked foam polyethylene sheet while holding both-side edges of the cross-linked foam polyethylene sheet; anda heater provided within the widening tunnel, which is for generating heat so as to make it easy to transform the cross-linked foam polyethylene sheet whose width is widened during transfer. 5. The apparatus as claimed in claim 1, wherein the sheet-attaching part comprises: heating rollers provided to attach the aluminum film on at least one surface of the widened cross-linked foam polyethylene sheet formed with the cells; and an aluminum film feeder provided at upper and lower sides of the frame at a rear end of the heating rollers, which is for feeding the aluminum film to be attached, to upper and lower sides of a front side of the heating rollers. 6. The apparatus as claimed in claim 5, wherein the upper roller of the cutting roller, the upper feeding roller of the feeding roller, and the cooling roller and the heating roller, positioned at an upper side, correspond to a thickness of the fed cross-linked foam polyethylene sheet, by a height adjusting means. 7. The apparatus as claimed in claim 1, wherein the cross-linked foam polyethylene sheet has a thickness of 5 mm. 8. The apparatus as claimed in claims 1, wherein an area of the cells formed in the cross-linked foam polyethylene sheet in a widened state has a range of 60 to 80% with respect to m2, and each of the cells formed in the cross-linked foam polyethylene sheet has a size of 2 cm2. 9. The apparatus as claimed in claim 1, wherein a width of a partition wall formed between the cells formed in the cross-linked foam polyethylene sheet is maintained in a range of 3 to 10 mm. 10. An apparatus for manufacturing a heat insulator, the apparatus comprising: a frame having a feeder provided at front side of the frame for feeding a cross-linked foam polyethylene sheet and a winder provided at rear side of the frame for winding a completed heat insulator;a cutting part provided at a leading side of the frame, which is for forming multiple cutoff slots in the cross-linked foam polyethylene sheet fed from the feeder;a widening part provided at a rear side of the cutting part, which is for transforming the cutoff slots into cells by widening a width of the cross-linked foam polyethylene sheet formed with the cutoff slots;a cooling part provided at a rear side of the widening part, which has cooling rollers to continuously maintain a widened width of the cross-linked foam polyethylene sheet and a shape of the cells transformed from the cutoff slots;a sheet-attaching part provided at a rear side of the cooling part, which is for attaching an aluminum film on one surface of the widened cross-linked foam polyethylene sheet formed with the cells so as to show high reflectivity and low emissivity; anda 2-sheet-attaching part provided at a rear side of the sheet-attaching part, which is for attaching an aluminum film on one surface of the cross-linked foam polyethylene sheet, which has an aluminum film attached on the opposite surface thereof by direct heat. 11. The apparatus as claimed in claim 10, wherein the 2-sheet-attaching part comprises: a burner for applying direct heat on one surface of the cross-linked foam polyethylene sheet, which has an aluminum film attached on the opposite surface thereof, drawn out from the sheet-attaching part, thereby melting a surface of the cross-linked foam polyethylene sheet; anda sheet-attaching roller provided between a rear side of the burner and the winder, which is for attaching the aluminum film on a molten surface of the cross-linked foam polyethylene sheet. 12. The apparatus as claimed in claim 10, wherein the cross-linked foam polyethylene sheet has a thickness of 5 mm. 13. The apparatus as claimed in claim 10, wherein an area of the cells formed in the cross-linked foam polyethylene sheet in a widened state has a range of 60 to 80% with respect to m2, and each of the cells formed in the cross-linked foam polyethylene sheet has a size of 2 cm2. 14. The apparatus as claimed in claim 10, wherein a width of a partition wall formed between the cells formed in the cross-linked foam polyethylene sheet is maintained in a range of 3 to 10 mm.
Boyce Joseph S. (Hanover MA) Freitas Glenn A. (Foxboro MA) Campbell Thomas G. (Concord MA), Method of forming a truss reinforced foam core sandwich structure.
Delage Andr (Le Pian Medoc FRX) Georges Jean-Michel (Gradignan FRX) Maumus Jean-Pierre (Cenon FRX), Method of manufacturing a honey comb structure of thermostructural composite material.
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