The invention discloses a vacuum cracking apparatus for a power battery and a cracking method thereof. The cracking device comprises a cylinder and further comprises a rolling device, a first sealing device, a cracking device, a second sealing device, a pyrolysis device and a third sealing device which are arranged from top to bottom. The cracking device for the power battery of the present invention is equipped with the first sealing device, the second sealing device and the third sealing device to isolate the cracking device from the pyrolysis device and be capable of realizing material transmission and gas isolation without interference with each other, so that gas stirring between an anaerobic zone and an aerobic zone is avoided; and by combing battery cracking and battery pyrolysis, with cracked gas discharged after cracking as a fuel for cracking and pyrolysis or preheating a pyrolysis device, resources are fully used.

A rotary furnace (1) for pyrolyzing a feedstock, the furnace (1) comprises a rotating vessel (12) having an upstream end (12A) with an inlet (16) for receiving feedstock and a downstream end (12B) with an outlet (17A, 17B) for egress of pyrolysis products, and a gas extraction pipe (13) extending within and along the rotating vessel (12) from the downstream end (12B), the gas extraction pipe (13) having an opening (18) upstream of the downstream end (12B) to accept gaseous components generated in use.

A delaboration chamber has an outer housing that can be sealed by a removable cover. The delaboration chamber has an inner floor. A first chamber region is formed underneath the inner floor by the inner floor and the outer housing. The first chamber region is filled with a flowable or solid medium. The inner floor has a recess for receiving an explosive object. The cover is connected to the outer housing in a shockproof manner. The cover has a pressure relief that has at least one deflection for the detonation gases.

Disclosed is a system and method for the recycling of waste composite feed materials such as printed circuit boards (PCBs), batteries, catalysts, plastic, plastic composites such as food packaging materials, for example Tetra Pak, mattresses, compact disks (CDs, DVDs), automobile shredder residue (ASR), electric cable wastes, liquid display panels, mobile phones of various sizes or combinations of the above using a new pyrolysis system and method.

An aspect of the present disclosure relates to a thermite bag, which may be used for the disposal of hazardous material. The thermite bag includes a sealable exterior pouch, a sealable interior pouch receivable within the exterior pouch, a thermite charge receivable within the sealable interior pouch and an igniter wire contacting thermite within the thermite charge. The thermite bag also includes a power supply electrically coupled to the ignitor wire and a trigger electrically coupled to the ignitor wire and power supply. In addition, the thermite bag includes a vent including a filter, wherein the vent is coupled to the sealable exterior pouch.

The invention discloses a vacuum cracking apparatus for a power battery and a cracking method thereof. The cracking device includes a cylinder and further includes a rolling device, a first sealing device, a cracking device, a second sealing device, a pyrolysis device and a third sealing device which are arranged from top to bottom. The cracking device for the power battery of the present invention is equipped with the first sealing device, the second sealing device and the third sealing device to isolate the cracking device from the pyrolysis device and be capable of realizing material transmission and gas isolation without interference with each other, so that gas stirring between an anaerobic zone and an aerobic zone is avoided; and by combing battery cracking and battery pyrolysis, with cracked gas discharged after cracking as a fuel for cracking and pyrolysis or preheating a pyrolysis device, resources are fully used.

An aspect of the present disclosure relates to a thermite bag, which may be used for the disposal of hazardous material. The thermite bag includes a sealable exterior pouch, a sealable interior pouch receivable within the exterior pouch, a thermite charge receivable within the sealable interior pouch and an igniter wire contacting thermite within the thermite charge. The thermite bag also includes a power supply electrically coupled to the ignitor wire and a trigger electrically coupled to the ignitor wire and power supply. In addition, the thermite bag includes a vent including a filter, wherein the vent is coupled to the sealable exterior pouch.

A process for the incineration of activated coal-supported PGM catalysts, the process comprising a joint incineration of a multilayer arrangement, wherein the multilayer arrangement includes (i) a top layer of particulate activated coal-supported PGM catalyst, (ii) a layer of coarse charcoal located beneath said top layer and, optionally, (iii) a layer of particulate coke located beneath the charcoal layer, and wherein an upward flow of oxidizing gas is homogeneously passed through said multilayer arrangement during the incineration.

An incinerator has a spherical chamber body to define an incineration chamber and includes a port structure with an opening that provides access to the incineration chamber. A hatch is pivotably attached to the port structure to provide access to the opening or to close the opening in the port structure. An incendiary device support member located within the incineration chamber to hold an ignitable incendiary device. A flammable panel member is located within the incineration chamber and positioned over the incendiary device support member. The panel member supports IEDs, explosive devices or biological agents for incineration. When the ignitable incendiary device is ignited, thermal energy is produced to incinerate the IEDs, explosive devices or biological agents positioned on the panel member.

A hand-held, disposable incinerator for medications and electronic storage media includes a body and a lid, a layer of insulation, and a chemical burn agent, which on ignition produces both heat and oxygen to destroy the contents. Exhaust gases pass through a non-combustible filter to remove most solid particles and contaminants, followed by a second, higher-efficiency filter. Hot gases exiting from the incinerator then desirably ignite again from their own heat, consuming remaining volatile organic matter distilled from the items being destroyed. An igniter, which may be a fuse, a pull-tab-activated pyrotechnic delay or an electronically remote-triggered igniter, provides a delay for the safety of the person using the incinerator. Heat generated within the burn chamber decomposes most organic materials, melts soft metals including aluminum and electronic solder, and renders data storage devices unreadable. At least an inner portion of the device may be safely discarded.