An item of equipment for separating bagged waste has a hopper, separation means for separating the waste, a scanner for classifying the waste, elements for opening the bagged waste, chutes with gates, classification means, an artificial vision camera, and a plurality of shredders. Thus, the shredders are able to shred the waste subsequent to the classification thereof by type of polymer and color, thanks to the artificial vision camera. The equipment enables the individual separation of the bagged waste for the subsequent treatment thereof, as frequently some bags of waste are adhered to others.

An item of equipment for separating bagged waste has a hopper, separation means for separating the waste, a scanner for classifying the waste, elements for opening the bagged waste, chutes with gates, classification means, an artificial vision camera, and a plurality of shredders. Thus, the shredders are able to shred the waste subsequent to the classification thereof by type of polymer and color, thanks to the artificial vision camera. The equipment enables the individual separation of the bagged waste for the subsequent treatment thereof, as frequently some bags of waste are adhered to others.

A deep cleaning method for highly contaminated soil comprises a feeding step, a washing step, a first separation step, a second separation step, a countercurrent washing step, and a wastewater treatment step. The countercurrent washing step is to receive the sand water that completed the second separation step. The sand water is introduced into a countercurrent washing tank from the top, and the clean water is injected into the bottom of the countercurrent washing tank to form a countercurrent washing state. The washed sand is discharged from the bottom of the countercurrent washing tank, and the mud washed from the sand is overflowed by the rising water flow and collected to a wastewater treatment unit. Through the backwashing step, the highly oil-contaminated soil with low mud content can also be applied to the water washing method, thereby expanding the treatable range of oil-contaminated soil.

A deep cleaning method for highly contaminated soil comprises a feeding step, a washing step, a first separation step, a second separation step, a countercurrent washing step, and a wastewater treatment step. The countercurrent washing step is to receive the sand water that completed the second separation step. The sand water is introduced into a countercurrent washing tank from the top, and the clean water is injected into the bottom of the countercurrent washing tank to form a countercurrent washing state. The washed sand is discharged from the bottom of the countercurrent washing tank, and the mud washed from the sand is overflowed by the rising water flow and collected to a wastewater treatment unit. Through the backwashing step, the highly oil-contaminated soil with low mud content can also be applied to the water washing method, thereby expanding the treatable range of oil-contaminated soil.

A deep cleaning method for highly contaminated soil comprises a feeding step, a washing step, a first separation step, a second separation step, a countercurrent washing step, and a wastewater treatment step. The countercurrent washing step is to receive the sand water that completed the second separation step. The sand water is introduced into a countercurrent washing tank from the top, and the clean water is injected into the bottom of the countercurrent washing tank to form a countercurrent washing state. The washed sand is discharged from the bottom of the countercurrent washing tank, and the mud washed from the sand is overflowed by the rising water flow and collected to a wastewater treatment unit. Through the backwashing step, the highly oil-contaminated soil with low mud content can also be applied to the water washing method, thereby expanding the treatable range of oil-contaminated soil.

A deep cleaning method for highly contaminated soil comprises a feeding step, a washing step, a first separation step, a second separation step, a countercurrent washing step, and a wastewater treatment step. The countercurrent washing step is to receive the sand water that completed the second separation step. The sand water is introduced into a countercurrent washing tank from the top, and the clean water is injected into the bottom of the countercurrent washing tank to form a countercurrent washing state. The washed sand is discharged from the bottom of the countercurrent washing tank, and the mud washed from the sand is overflowed by the rising water flow and collected to a wastewater treatment unit. Through the backwashing step, the highly oil-contaminated soil with low mud content can also be applied to the water washing method, thereby expanding the treatable range of oil-contaminated soil.

A vibrating sorting table for separating loosely attached parts from a workpiece includes a bench. The bench comprises a bottom. Each of a plurality of supports is coupled to and extends substantially vertically from a respective edge of the bottom. A top is flexibly coupled to each of the supports. The top is substantially parallel to the bottom. The top is movable relative to the supports and the bottom. A pair of rims is coupled singly to opposing sides of the top. The rims separate a workpiece positioned on the bench from an upper face of the top. A vibration unit is coupled to a lower face of the top. The vibration unit is positioned to impart vibrational forces to the top, such that the workpiece coupled to the top vibrates. Parts of the workpiece that are loosely attached separate from the workpiece and fall to the upper face of the top.

The invention relates to a method and system for the environmental remediation of materials that are contaminated with heavy minerals, such as heavy metals. The invention finds utility in removing heavy minerals from materials such as soils, sediments, mine tailings and ores. The invention provides a means for removing heavy minerals from contaminated materials without the use of water while reducing the generation of dust. Thus, the invention provides an environmentally friendly method for the remediation of sites that are contaminated with heavy minerals.

The invention relates to a method and system for the environmental remediation of materials that are contaminated with heavy minerals, such as heavy metals. The invention finds utility in removing heavy minerals from materials such as soils, sediments, mine tailings and ores. The invention provides a means for removing heavy minerals from contaminated materials without the use of water while reducing the generation of dust. Thus, the invention provides an environmentally friendly method for the remediation of sites that are contaminated with heavy minerals.

The invention relates to a method and system for the environmental remediation of materials that are contaminated with heavy minerals, such as heavy metals. The invention finds utility in removing heavy minerals from materials such as soils, sediments, mine tailings and ores. The invention provides a means for removing heavy minerals from contaminated materials without the use of water while reducing the generation of dust. Thus, the invention provides an environmentally friendly method for the remediation of sites that are contaminated with heavy minerals.