Patent ID: 11905574
Assignee: FRANCISCO JAVIER JIMéNEZ GUZMáN
Field: Chemical engineering (Chemistry)
Classification: CPC B  C  Y | IPC B  C

Claim 0:
1. A system for the physical-mechanical recovery and refining of non-ferrous metals from electronic scrap, wherein the electronic scrap comprises minerals and metals, characterized in that said system comprises:
A hammer mill (1), arranged to crush electronic scrap waste to a homogeneous particle size; an air chamber (3), arranged in and connected to an outlet of the hammer mill (1), said air chamber (3) being arranged to receive crushed electronic scrap waste from the hammer mill (1) and incorporated into a wind current caused by the movement of said hammer mill (1); a separation chamber (4) having a rebound screen arranged at its bottom, said rebound screen having holes in its surface, and said separation chamber (4) being arranged to receive and disperse the crushed electronic scrap waste incorporated into the wind current in such a way that the crushed electronic scrap waste is dispersed until it hits the rebound screen, and heaviest crushed electronic scrap waste is deposited on the rebound screen, while lighter crushed electronic scrap waste is driven back towards the separation chamber (4), by a turbulence generated by the wind current coming from the hammer mill (1); a blower arranged to direct a transverse air stream with a flow of 150-250 m3/h into the separation chamber (4), thus redirecting the lighter crushed electronic scrap waste towards an outlet duct; and an extractor arranged to provide a suction flow of 1700 to 2100 m3/h, to drag said lighter crushed electronic scrap waste towards a bag filter (7);
a dosing box (8), which is connected to the separation chamber (4), aid dosing box (8) being arranged to receive the heaviest crushed electronic scrap waste that passes through the holes of the rebound screen and redirects it towards a second conveyor belt (9); a transverse barrel feed hopper (10) arranged to receive the heaviest crushed electronic scrap waste from the second conveyor belt (9), the heaviest crushed electronic scrap waste being intercepted by a transversal air current of 130-170 m3/h in said transverse barrel feed hopper (10), in such a way that lightest materials of the heaviest crushed electronic scrap waste are sent towards an outlet; an extractor (11) arranged at said outlet to generate a suction current between 1700 and 2300 m3/h, which drags the lightest materials of the heaviest crushed electronic scrap waste which are trapped by the suction current, and to redirect said lightest materials towards the bag filter (7);
A screen or retention mesh, arranged in a lower part of the transverse barrel feed hopper (10) to allow the heaviest crushed electronic scrap waste to pass through it; an oscillating screen (12) arranged to classify the heaviest crushed electronic scrap waste into three sizes: a large size that is greater than 3 mm; a medium size ranging between 1 to 3 mm and; a fine size that is less than 1 mm, wherein medium and fine-sized heaviest crushed electronic scrap waste is deposited on a third conveyor belt (16), and the heaviest crushed electronic scrap waste of large size is rejected; a cyclone (14) arranged to receive the rejected heaviest crushed electronic scrap waste of large size from the oscillating screen (12) by means of a blower (13); a second mill (15) connected to the cyclone (14) and arranged to decrease the size of the heaviest crushed electronic scrap waste of large size from the cyclone (14) and send it back to the transverse barrel feed hopper (10);
A magnetic drum (17), arranged to receive the medium and fine-sized heaviest crushed electronic scrap waste from the third conveyor belt (16); a combined rotary screen (18) in communication with the magnetic drum (17), wherein the magnetic drum (17) is further arranged to separate said medium and fine-sized heaviest crushed electronic scrap waste into ferrous metals of the heaviest crushed electronic scrap waste and non-ferrous metals of the heaviest crushed electronic scrap waste; the ferrous metals of the heaviest crushed electronic scrap waste being sent to a parallel production line, while the non-ferrous metals of the heaviest crushed electronic scrap waste are deposited on the combined rotary screen (18), and wherein the combined rotary screen (18) is arranged to remove the non-ferrous metals smaller than 1 mm, sending them to a wet densimetric table (18a) or wiffley table where a separation and treatment of fine powders is carried out to eliminate fine powders from the non-ferrous metals, then transferring the free-fine powders non-ferrous metals to a first air-operated serpentine dryer (18b), while the non-ferrous metals of medium size (1-3 mm) are sent to a second stage of the combined rotary screen (18); a rotating drum arranged in the second stage of the combined rotary screen (18) to receive the non-ferrous metals of medium size and sufficient amount of water to form a homogeneous mixture; a second densimetric table (19), arranged to receive the homogeneous mixture from said combined rotary screen (18), and remove contaminants from the homogeneous mixture of non-ferrous metals;
A rotary screen (20), arranged to receive the homogeneous mixture of non-ferrous metals with a size between 1 and 3 mm from the second densimetric table (19) and remove any excess water contained in the homogeneous mixture of non-ferrous metals; a second air-operated serpentine dryer (21) arranged to dry the homogeneous mixture of non-ferrous metals and thus obtain dry non-ferrous metals; a cyclone (22) positioned on a dosing silo (23) and arranged to receive the dry non-ferrous metals from the second air-operated serpentine dryer (21) and remove the contaminants contained in said dry non-ferrous metals, wherein free-contaminants and dry non-ferrous metals are stored in the dosing silo (23) to be fed by a variable speed worm to a centrifugal granulator mill (24), the centrifugal granulator mill (24) being arranged to reduce the free-contaminants and dry non-ferrous metals in a controlled way to a homogeneous size and weight;
A cyclone (25) arranged to receives the non-ferrous metals from the centrifugal granulator mill (24), and eliminate fine materials produced during the reduction of the free-contaminants and dry non-ferrous metals to a homogeneous size and weight, wherein said fine materials are sent towards a bag filter (26), while the non-ferrous metals are dispensed through an electrovalve towards a fourth conveyor belt (27); a magnetic head being arranged in one end of said fourth conveyor belt (27) for the elimination of magnetic residues;
A third oscillating screen (28) arranged to receives the non-ferrous metals free of magnetic residues from the magnetic head, and separate the non-ferrous metals into two sizes: a small size of 0.5 to 1 mm and a medium size that ranges between 1 to 2 mm; the non-ferrous metals greater than 3 mm being sent to the second mill (15) for reprocessing, while fine powders less than 0.5 mm are discarded;
A first two-way densimetric separator (29) having an upper outlet and a lower outlet, said first two-way densimetric separator (29) being arranged to receive and separate the medium-sized non-ferrous metals from the third oscillating screen (28), in such a way that clean copper comes out of the upper outlet, and contaminated aluminum comes out of the lower outlet, said contaminated aluminum being transferred through a pedestal or donkey to a second two-way densimetric separator (30), said second two-way densimetric separator (30) being calibrated differently than the first two-way densimetric separator (29) and arranged to receive and separate the contaminated aluminum from the first two-way densimetric separator (29), wherein said second two-way densimetric separator (30) has an upper outlet through which clean aluminum comes out and a lower outlet through which garbage comes out; and
A third two-way densimetric separator (31) having an upper outlet and a lower outlet, said third two-way densimetric separator (31) being arranged to receive and separate the small size non-ferrous metals from the third oscillating screen (28) in such a way that clean copper comes out of the upper outlet, and aluminum contaminated comes out of the lower outlet, said clean copper having a smaller size than the size of the clean copper that comes out of the first densimetric separator (29), and said contaminated aluminum being transferred by means of a pedestal or donkey to a fourth two-way densimetric separator (32), said fourth two-way densimetric separator (32) being calibrated differently than the third two-way densimetric separator (31) and arranged to receive and separate the contaminated aluminum from the third two-way densimetric separator (31), wherein said fourth two-way densimetric separator (32) has an upper outlet through which clean aluminum comes out, and a lower outlet through which garbage comes out, said clean aluminum having a smaller size than the size of the clean aluminum that comes out of the second two-way densimetric separator (30).