A panel and a method for manufacturing thereof where the panel includes a first layer comprising a first blend of paper fragments and plastic fragments; a second layer comprising a second blend of paper fragments and plastic fragments, wherein the paper fragments and plastic fragments of the second blend are coated with an adhesive; and a third layer comprising the first blend of paper fragments and plastic fragments, wherein the second layer is disposed between the first layer and the third layer, and wherein the first layer, the second layer, and the third layer are combined to form the panel using heat and pressure. In another embodiment, the paper fragments and plastic fragments of the first blend, not the second blend, are coated with an adhesive.

A safe discharge method for waste lithium ion batteries includes steps of mixing the waste lithium ion batteries and conductive particles in a discharge chamber to make the waste lithium ion batteries to discharge, calculating an internal resistance of the discharge chamber according to pressurization pressure; calculating a discharge rate of the waste lithium ion batteries; dynamically adjusting the pressurization pressure to keep the discharge rate of the waste lithium ion batteries to be 0.1-3 C; monitoring an internal temperature of the discharge chamber in real time; when the internal temperature is greater than an early warning temperature, reducing the pressurization pressure by 20%-60%; when the internal temperature is greater than a warning temperature, relieving the pressurization pressure to 0 N, reducing the pressurization pressure by 60%-90% after the internal temperature drops below the early warning temperature, and re-compacting to discharge the waste lithium ion batteries.

A safe discharge method for waste lithium ion batteries includes steps of mixing the waste lithium ion batteries and conductive particles in a discharge chamber to make the waste lithium ion batteries to discharge, calculating an internal resistance of the discharge chamber according to pressurization pressure; calculating a discharge rate of the waste lithium ion batteries; dynamically adjusting the pressurization pressure to keep the discharge rate of the waste lithium ion batteries to be 0.1-3 C; monitoring an internal temperature of the discharge chamber in real time; when the internal temperature is greater than an early warning temperature, reducing the pressurization pressure by 20%-60%; when the internal temperature is greater than a warning temperature, relieving the pressurization pressure to 0 N, reducing the pressurization pressure by 60%-90% after the internal temperature drops below the early warning temperature, and re-compacting to discharge the waste lithium ion batteries.

A dewatering apparatus having a size reduction portion adapted to reduce the size of one or more items to be dewatered, and a separation portion in fluid communication with the size reduction portion, the separation portion adapted to substantially separate the liquid and solid components of the one or more items.

A dewatering apparatus having a size reduction portion adapted to reduce the size of one or more items to be dewatered, and a separation portion in fluid communication with the size reduction portion, the separation portion adapted to substantially separate the liquid and solid components of the one or more items.

The present disclosure provides a disassembly mechanism, a disassembly system of a power battery pack with the disassembly mechanism and a disassembly method of the power battery pack. The above disassembly mechanism includes a die base assembly, a pressing assembly and a removal tool assembly. The pressing assembly is movably connected to the die base assembly, and is used to abut against and press a single battery of a power battery pack. The removal tool assembly is slidably connected to the die base assembly and elastically connected to the die base assembly. The removal tool assembly is used to squeeze and separate a casing and the single battery of the power battery pack. The above disassembly mechanism can realize automatic disassembly of the power battery pack with few manual intervention, and solves the problem of low efficiency in the recycling and disassembly process of the power battery pack.

The present disclosure provides a disassembly mechanism, a disassembly system of a power battery pack with the disassembly mechanism and a disassembly method of the power battery pack. The above disassembly mechanism includes a die base assembly, a pressing assembly and a removal tool assembly. The pressing assembly is movably connected to the die base assembly, and is used to abut against and press a single battery of a power battery pack. The removal tool assembly is slidably connected to the die base assembly and elastically connected to the die base assembly. The removal tool assembly is used to squeeze and separate a casing and the single battery of the power battery pack. The above disassembly mechanism can realize automatic disassembly of the power battery pack with few manual intervention, and solves the problem of low efficiency in the recycling and disassembly process of the power battery pack.

A method for manufacturing a recyclable article from municipal solid waste (MSW) without addition of binders is disclosed. The method includes aspects of processing, a proportionate quantity of biodegradable waste and non-biodegradable waste to form a mixture. The processed mixture is loaded into a mould placed in a melter (9). The processed mixture is subsequently melted in the melter (9) at a pre-determined temperature and pre-determined pressure, where the non-biodegradable waste circumscribes and form a bond with the biodegradable waste during melting. The melted mixture is compressed in a compression moulding device (10) at a pressure ranging from 0.1 Kg/cm.sup.2 to 3.0 Kg/cm.sup.2. Further, the compression of the melted mixture is carried out under supply of a coolant for solidifying and forming the article.

A method for manufacturing a recyclable article from municipal solid waste (MSW) without addition of binders is disclosed. The method includes aspects of processing, a proportionate quantity of biodegradable waste and non-biodegradable waste to form a mixture. The processed mixture is loaded into a mould placed in a melter (9). The processed mixture is subsequently melted in the melter (9) at a pre-determined temperature and pre-determined pressure, where the non-biodegradable waste circumscribes and form a bond with the biodegradable waste during melting. The melted mixture is compressed in a compression moulding device (10) at a pressure ranging from 0.1 Kg/cm.sup.2 to 3.0 Kg/cm.sup.2. Further, the compression of the melted mixture is carried out under supply of a coolant for solidifying and forming the article.

The invention relates to an apparatus for processing solid waste, which comprises a base provided with linear rails (10) on which a carriage (20) moves, said carriage being held on the rails by castors and supported by a hydraulic cylinder; a collection unit arranged at the head end of the rails (10) and provided with an upper opening (30) that receives the waste and transfers it by gravity to a processing unit (40) comprising conical elements (not depicted) in the inner region thereof, and, centrally, a shaft with a helicoid (41) surface, said shaft (41) being rotated by a motor with a motor-reduction unit (42); and an extrusion unit (50) that receives the triturated waste from the collection unit, said extrusion unit (50) comprising a base provided with holes and a conical opening opposite the area of inflow of the waste from the processing unit (40).