The present invention provides a glass wool cutting device. The device includes a cutting section housing that has a cutting section chamber, a feed port that is connected to the cutting section chamber, and a discharge port that is connected to the cutting section chamber. A stationary knife is disposed on the cutting section housing to protrude into the cutting section chamber and a movable cutter that has a rotary support body is disposed in the cutting section chamber and a movable knife is supported on the rotary support body to apply a shearing force to the glass wool together with the stationary knife. Additionally, a cutter actuator provides a driving force to the rotary support body.

A system for processing scrap material that includes a variable-power electromagnetic drum separator wherein shredded scrap material is placed in free fall at a position proximate the electromagnetic drum separator. A first fraction of the scrap material is attracted to the electromagnetic drum separator and is carried under the rotational axis of the electromagnetic drum separator thereby separating the first fraction of material from a second fraction of the material which continues to free fall and wherein the first fraction is a low-copper ferrous material with the second fraction having a higher non-ferrous content than the first fraction. A magnetic drum separator may be positioned upstream of the variable-power electromagnetic drum separator and be used to separate non-ferrous materials. The variable-power electromagnetic drum separator may be adjusted so that the second fraction includes some ferrous material. A robotic picker may be used to remove undesirable materials from the second fraction.

A system for processing scrap material that includes a variable-power electromagnetic drum separator wherein shredded scrap material is placed in free fall at a position proximate the electromagnetic drum separator. A first fraction of the scrap material is attracted to the electromagnetic drum separator and is carried under the rotational axis of the electromagnetic drum separator thereby separating the first fraction of material from a second fraction of the material which continues to free fall and wherein the first fraction is a low-copper ferrous material with the second fraction having a higher non-ferrous content than the first fraction. A magnetic drum separator may be positioned upstream of the variable-power electromagnetic drum separator and be used to separate non-ferrous materials. The variable-power electromagnetic drum separator may be adjusted so that the second fraction includes some ferrous material. A robotic picker may be used to remove undesirable materials from the second fraction.

A food waste processor including a food waste inlet; a grinding station located downstream of the inlet, wherein the grinding station includes a grinding apparatus which grinds the food waste and increases pressure on the food waste; a liquid exit path from the grinding station, wherein the liquid exit path includes a filter; and a solid exit path from the grinding station, wherein a liquid component of the ground food waste is forced through the filter and exits the grinding station via the liquid exit path and a solid organic component of the ground food waste exits the grinding station via the solid exit path; the liquid exit path is in communication with a separator; the solid exit path is in communication with a compressed food waste collector; the separator separates the liquid component into water and an organic component which includes entrained food particles; the separator including a water exit path in communication with a water treatment station, and an organic component exit path in communication with an organic processing station; the organic processing station includes a storage chamber, a heater, a pump having an inlet and an outlet and an organic conduit, wherein the heater heats the storage chamber, the inlet of the pump is in communication with the storage chamber, the outlet of the pump is in communication with an inlet end of the conduit, and an outlet end of the conduit defines an organic component outlet port disposed downstream of the food waste inlet and upstream of the grinding station.

A food waste processor including a food waste inlet; a grinding station located downstream of the inlet, wherein the grinding station includes a grinding apparatus which grinds the food waste and increases pressure on the food waste; a liquid exit path from the grinding station, wherein the liquid exit path includes a filter; and a solid exit path from the grinding station, wherein a liquid component of the ground food waste is forced through the filter and exits the grinding station via the liquid exit path and a solid organic component of the ground food waste exits the grinding station via the solid exit path; the liquid exit path is in communication with a separator; the solid exit path is in communication with a compressed food waste collector; the separator separates the liquid component into water and an organic component which includes entrained food particles; the separator including a water exit path in communication with a water treatment station, and an organic component exit path in communication with an organic processing station; the organic processing station includes a storage chamber, a heater, a pump having an inlet and an outlet and an organic conduit, wherein the heater heats the storage chamber, the inlet of the pump is in communication with the storage chamber, the outlet of the pump is in communication with an inlet end of the conduit, and an outlet end of the conduit defines an organic component outlet port disposed downstream of the food waste inlet and upstream of the grinding station.

System having an apparatus (10) for shredding hygiene products (12), which operates within a revolving device (22).

System having an apparatus (10) for shredding hygiene products (12), which operates within a revolving device (22).

Methods and systems for preparing ore for precious metal extraction is provided. For example, a method comprises crushing ore; grinding the crushed ore; screening the ground ore to separate ore particles into a first group of large ore particles and a first group of small ore particles; crushing the first group of large ore particles; screening the crushed ore to separate into a second group of large ore particles and a second group of small ore particles; separating the second group of small ore particles from the screen into a third group of large particles and a third group of small particles; milling the third group of large ore particles; separating milled particles into a fourth group of large particles and a fourth group of small particles; and sending the third and fourth group of small particles for further metal extraction processing.

Methods and systems for preparing ore for precious metal extraction is provided. For example, a method comprises crushing ore; grinding the crushed ore; screening the ground ore to separate ore particles into a first group of large ore particles and a first group of small ore particles; crushing the first group of large ore particles; screening the crushed ore to separate into a second group of large ore particles and a second group of small ore particles; separating the second group of small ore particles from the screen into a third group of large particles and a third group of small particles; milling the third group of large ore particles; separating milled particles into a fourth group of large particles and a fourth group of small particles; and sending the third and fourth group of small particles for further metal extraction processing.

An apparatus to recover incoherent material present in a process fluid to be treated (F1) comprises a separation device (13) to separate, by means of centrifugal action, the incoherent material (M) from the process fluid (F) and a pumping unit (12) configured to remove the process fluid to be treated (F1) from a collection zone (11) and send it to the separation device (13).