A system for preparing a medicinal substance containing full spectrum of therapeutically desirable substances in naturally occurring proportions found in hemp plants, carried out by grinding a whole hemp plant to produce fine particles material, and exposing the fine particles material to an elevated pressure (11 PSI-15 PSI) and a reaction temperature maintained in a range of 230 F-250 F which is below a boiling point of the phyto-cannabinoids, terpenes and flavonoids, thus providing enhanced conditions for solvent-free extraction of the therapeutically desirable substances and diffusing the extracted substances into the carrier oil at an enhanced rate. Thus producing an infused oil final product containing a full spectrum phyto-cannabinoids, terpenes and flavonoids in naturally occurring proportions.

A system for refining mixed material streams, includes a receptacle for receiving an input stream; a mill grinding the input stream to reduce particle size and output a milled stream; a first filter having first filtration holes which filter the milled stream to remove a first portion having particle sizes larger than the first filtration holes and to output as a sifted stream a second portion having particle sizes smaller than the first filtration holes; a second filter having second filtration holes which are smaller than the first filtration holes, the second filtration holes filtering the sifted stream to output a filtered stream; and a density separator receiving the filtered stream and receiving a liquid. The filtered stream combined with the liquid forms a mixture, and the density separator separates the mixture into at least a first output and a second output having a greater density than the first output.

A composite material is produced from carpet waste and a binding agent, in intimate association, and may also include wood fiber or chips and/or other additives. A method of manufacturing a composite material includes shredding carpet waste, coating the carpet waste with a binding agent, and subjecting the shredded, coated carpet waste to elevated heat and pressure. As an additional step, the composite material may be actively cooled to prevent deformation of the material.

Systems and methods for cooling and processing materials are disclosed.

A freezer includes a grinder to obtain a ground meat; a mixer to add fat to the ground meat; a payload bay to receive the ground meat; a plurality of evaporators coupled to the payload bay with a multiplicity of coolant tubes in each evaporator, wherein each tube enters and then exits the payload bay, further comprising one or more cryogenic valves coupled to the coolant tubes; a pump to force coolant flowing through the evaporators; and a processor with code for: chopping the ground meat and during chopping, adding salt and ice to the ground meat being chopped and adding liquid nitrogen to maintain the temperature of the meat being chopped below 5 C. to obtain a chopped meat product; adding fat to the chopped meat product and then chopping the fat and adding liquid nitrogen to maintain the temperature of the chopped meat product and fat being chopped between 1 C. and 10 C. to obtain a chopped meat and fat product, wherein the ground meat, added fat, ice and salt are present in amounts so that the chopped meat and fat product has a fat content of from 1% to 20% by weight based upon the weight of the chopped meat and fat product.

A double locking door assembly for a hollow vessel having a longitudinal axis and an interior for receiving a process material, the double locking door assembly including a door, a main annular locking ring, which secures the door to a front portion of the vessel, and a locator annular locking ring, the locator annular locking ring configured to remove and attach the door to the front portion of the vessel.

A crushing method for galvanic cells with high energy densities in which a mixture of used cells is placed inside an insulated container and carbon dioxide as dry ice is added to this mixture as a cooling medium. Dry ice is added to the mixture of used galvanic cells at a volumetric ration of 0.5:1 to 2:1. The mixture of used cells with dry ice is cooled down from ?20? C. to ?50? C. and is subsequently fed to the crushing device and subjected to crushing. A stream of used galvanic cells and a stream of dry ice granules are preferably fed simultaneously to the insulated container of the crushing device, and this mixture is forwarded to the working part of the crushing device. At the end of galvanic cell crushing, the mixture of air and gaseous carbon dioxide is returned to the insulated container.

The present disclosure provides for a novel pig design and method of retrieval based on thermal ablation. The pig comprises an external layer and an inner core, where the inner core further comprises at least one incendiary charge comprising at least one exothermic material. When ignited via an ignition source, the incendiary charge releases the exothermic material into one or more thermal dispersion channels. The exothermic material melts the interior of these thermal dispersion channels thereby distributing the exothermic material throughout the pig device causing its destruction via thermal ablation. The destroyed pig can then be easily retrieved from its location in a pipe, as detected via radio signals, without the need for costly excavation of large sections of the pipe.

The present disclosure provides for a novel pig design and method of retrieval based on thermal ablation. The pig comprises an external layer and an inner core, where the inner core further comprises at least one incendiary charge comprising at least one exothermic material. When ignited via an ignition source, the incendiary charge releases the exothermic material into one or more thermal dispersion channels. The exothermic material melts the interior of these thermal dispersion channels thereby distributing the exothermic material throughout the pig device causing its destruction via thermal ablation. The destroyed pig can then be easily retrieved from its location in a pipe, as detected via radio signals, without the need for costly excavation of large sections of the pipe.

A method of recovering an electrode material comprising: providing an electrode laminate, wherein the electrode laminate comprises a current collector foil and an electrode material laminated on at least one surface of the current collector foil; supplying moisture to the electrode material; freezing the moisture supplied to the electrode material; and crushing the electrode material and separating the electrode material from the current collector foil by applying a mechanical impact to the frozen electrode material and blowing a gas.