The peeling member is disposed inside the inner tank. The switching mechanism is provided for switching between the state of rotating the peeling member in the interlocking manner with the inner tank and the state of being disconnected the peeling member from the inner tank. With the peeling member disconnected from the inner tank, one of them is rotated, the used paper diaper stored is peeled off from the inner surface of the inner tank, and then, the used paper diaper processed in the processing tank is discharged from the bottom of the processing tank to the take-out unit via the opening and closing unit.

Multiple-can aerosol puncturing systems that are capable of puncturing multiple aerosol cans in a single operation are disclosed. A can holder with multiple chambers and a movable lid are used to contain the aerosol cans. A vertically movable actuation plate with multiple hollow puncturing pins is raised toward the can holder to puncture the lids of the aerosol cans. The heights of the puncturing pins may be staggered in order to puncture the lids sequentially during the same draining operation.

Provided is a used paper diaper processing apparatus in which a water absorption function of a superabsorbent polymer that absorbs water contained in excrement is lowered and water is removed by mixing the superabsorbent polymer and a chemical containing divalent metal ions in an outer tank, and in which weight is reduced by dehydration after an amount of water contained in a used paper diaper is lowered. In the apparatus, a lower portion of the outer tank can be opened and closed, so that weight reduction processing and a series of operations including taking-out are possible. Since an operator is not required to take out the used paper diaper after processing directly from the outer tank, it is possible to reduce work and hygiene burdens on the operator.

[Object] To use fibrous dust or particulate dust which were simple wastes in the past as resources. To improve treatment capacity dramatically.

[Solving Means] Non-metal dust which is further pulverized into a small particle size in a pulverizing step S10 through a crushing step Si of crushing wastes such as waste automobiles, waste home appliances, and waste office furniture into a predetermined size, an iron component separation and collection step S3 of separating and collecting an iron component, a non-ferrous component separation and collection step S4 of separating and collecting a non-ferrous component, a metal component separation and collection step S5 of sorting a metal component, wind power sorting steps S2, S6, S8, and S9 of sorting floating fibrous dust and a settled crushed material by wind power, and a shredding step S7 of shredding the settled crushed material into a predetermined size is separated into metal scraps such as copper, aluminum, and iron, fibrous dust, and particulate dust in a separating step S11. Fibrous dust and particulate dust are separately collected and are used as various fuel resources for household, business, and industry.

Detonable devices such as charged air bag inflators are fed to a shred tower at a controlled feed rate via a feed valve. Water spray and/or water baths in the shred tower prevent sparking and begin to solubilize chemicals while the inflators are fed to primary and optional secondary shredders respectively performing course and fine shreds. A sump receives the shredded material which continues solubilize and separate chemicals from metal. A conveyor lifts solids from the sump. Dewatered solids are fed to a receiving box for metal scrap recycling.

A process for recycling aerosol cans. The process includes the steps of draining the materials of the aerosol cans, collecting the materials of the aerosol cans, and refining the contents of the aerosol cans into original products that are available for resale. The step of draining the materials of aerosol cans is done by crushing the aerosol cans in an inert atmosphere and creating a metal brick from the aerosol cans. The materials are then drained into separator tanks where they can be separated and refined for resale.

An access device is provided for access to a fluid tank, especially a fluid tank of a ship. The access device includes a drill, a thread-forming unit, a hollow body with an external thread and a connection plate. The hollow body is provided with a valve.

An apparatus for draining a container comprises a vessel with a top opening configured such that the container in an upright orientation can pass downward into the vessel through the top opening. A knife assembly mounted under the top opening has a pointed upper end with right and left blades sloping downward and laterally away from the pointed upper end. The pointed upper end and the blades are configured to cut a flap in a floor of the container when the container is lowered through the top opening and pushed downward against the knife assembly. A push member pushes the flap upward from its remaining attachment along one side thereof as the container is pushed downward. The vessel can be mounted on a stand and include vertical exterior grooves configured to engage corresponding vertical stand members to prevent rotation of the vessel with respect to the stand during use.

A puncturing device for pressurized containers comprises an elongated housing member defining an elongated cavity with openings at first and second ends thereof for receiving an inverted pressurized container at the first end, the housing member including an attachment member for securing the second end of the housing member to a collection receptacle. A non-sparking puncturing member, is mounted within the housing member for piercing a nozzle-end of the pressurized container at its domed top. A counter records each action of the puncture pin. Gases and residual contents are released into the receptacle through the hollow core of the puncture pin. An auxiliary support member is mounted on the housing member for stabilizing relative movement between the housing member and the receptacle. A force-applying apparatus is mounted on the housing member for forcing the pressurized container onto the puncture pin.

A combination cleaning and disposal assembly for safely cleaning and rendering unusable a jug containing a hazardous chemical residue. A body supports a receiving chamber for receiving the jug. A manifold is supported by the body and has a plurality of spikes arrayed toward the jug. A pressurized fluid source is communicated to the manifold such that, upon an inter-displacement occurs between the manifold and the container, the spikes are caused to pierce the container, the pressurized fluid being caused to issue from the spikes to clean an interior of the container. A floor of the chamber has irregular surfaces to assist in deforming the jug during puncturing and outflow of contaminated fluid. A drain is located underneath the jug receiving chamber which collects and segregates the fluid contaminated with the chemical residue for securing disposal concurrent with removing and disposing of the cleaned and punctured jug.