The present invention discloses low cost, on-site, efficient, and compact (stationary or mobile) system for continuous (non-batch operation) conversion of waste to usable products such as sources of energy, fertilizer, etc.

The present invention discloses low cost, on-site, efficient, and compact (stationary or mobile) system for continuous (non-batch operation) conversion of waste to usable products such as sources of energy, fertilizer, etc.

A waste processing machine for reducing material and having a feed assist system. A cutting assembly on a frame reduces material. A feed system on the frame directs material toward the cutting assembly. A winch assembly includes a line with a line end for securing material, and a driver on the frame to urge the line end toward the driver. A keeper fixed to the frame secures the line end. A sensor detects utilization between: a docked configuration with the line tensioned against between the driver and the keeper; and an undocked configuration with the line loosened. A control unit allows operation of the feed system in the docked configuration, and interrupts the feed system in the undocked configuration. A feed mechanism actuation bypasses the interrupted operation to advance material for a bypass period, and a limit mechanism overrides operation of the feed mechanism for a subsequent limit period.

The invention discloses a pulverizing and packaging device for crushing glass, comprising a casing, wherein the casing is provided with an opening chamber with an opening upward, and the working chamber is provided with a collecting mechanism, and the collecting mechanism can collect common garbage. The working chamber is further provided with a pulverizing mechanism capable of pulverizing the crushed glass, and the lower side of the pulverizing mechanism is provided with a packing mechanism, and the working chamber is further provided There is a closing mechanism, The device is simple to operate, after the broken glass is thrown in, the glass is temporarily stored, and the cover is covered. After the glass is crushed into the garbage bag, the device can automatically pack the garbage bag, avoiding the contact between the person and the glass, and reducing the glass. The possibility of scratching.

A method of processing waste lead-acid batteries includes a crushing step, a sorting step, a plastic fragment treating step, and a plastic bit recycling step. Through the four steps, waste lead-acid batteries are turned into lead fragments, high-density plastic fragments, and plastic bits, which are recyclable as reusable materials, respectively. Moreover, waste liquid and waste gas in the waste lead-acid batteries are sent to a waste liquid treating equipment and a waste gas treating equipment, respectively, for further appropriate treatment. Therefore, the method may appropriately recycle useful materials of the waste lead-acid batteries and prevent the waste liquid and the waste gas from polluting the environment.

An appliance is disclosed for the size-reduction and drying of waste material. An essentially funnel-shaped vessel has a cylindrical attachment, on which at least two air inlets for introducing compressed air (L) are arranged in a manner distributed over a periphery of the cylindrical attachment, with an exit opening for size-reduced material (G) on a base of the funnel-like vessel. An air outflow opening is larger in diameter than the exit opening and lies opposite the exit opening. An ultrasonic nozzle with a Venturi function arranged on each of the at least two air inlets which are distributed over the periphery of the cylindrical attachment such that fed air (L) will be introduced in a peripheral direction of the cylindrical attachment and of the funnel-shaped vessel.

A waste separator for attachment to a sink drain pipe is provided, the waste separator comprising: a transverse pipe, the transverse pipe including a proximal end, a distal end, a sidewall therebetween, a solid waste outlet at the distal end and a magnetic flange on the sidewall, the transverse pipe defining a transverse bore, the transverse bore housing a motor-driven auger and a cylindrical filter between the motor-driven auger and the transverse pipe sidewall; a sink wastewater inlet in a vicinity of the proximal end, the sink wastewater inlet normal to the transverse bore and in fluid communication with the transverse bore; a normally-closed solenoid valve, the normally-closed solenoid valve in a vicinity of the distal end of the transverse pipe; a lower vessel, the lower vessel including a waste water outlet, the lower vessel defining an interior, the interior in fluid communication with the transverse bore proximate the proximal end; and a microprocessor, the microprocessor in electronic communication with the normally-closed solenoid valve.

Aspects of the present disclosure include devices, systems, methods, and control systems for processing waste into usable products, such as fuel stock, soil additives, and usable byproducts. Various system components may include: 1) a material loading area; 2) a pre-shredder; 3) a magnet based separator; 4) an eddy current separator; 5) additional sorting devices, such as a ballistic separator and/or an optical separator; 6) a mechanical pulverizer, such as a vertical shaft impactor (VSI); 7) a moisture separation device, such as a cyclone; 8) a compressor, such as a ram baler; 9) a packager, such as a bale wrapper; 10) analyzers, such as for moisture and caloric data analysis; 11) a thermal pressure chamber, such as a thermal screw; and 12) a control system to control operation of the system.

A portable shredder unit includes a lightweight housing with an interior cavity divided into a battery storage cavity and a collection cavity, said housing includes a top opening, two opposite ends, two opposite side walls, and a floor; a removable lid attached to said top opening on said housing; a high capacity electric shredder component configured to shred paper, said shredder component includes at least one feeding slot opening, an electric shredding mechanism, and electric motor and an exit discharge opening said shredder component being oriented on said lid so that, said feeding slot opening is exposed when the lid is placed over the top opening of said housing and said exit discharge opening is oriented above and over said collection cavity in said housing so that shredded material exiting the exit discharge opening is deposited into said collection cavity; at least one pair of wheels attached to said housing near one said end; a handle attached to said housing; a GFCI receptacle having a ground wire; a 110 VAC main cable with a male electrical plug attached to one end configured to manually plug into an external 110 VAC female plug, and an opposite end being connected to said GFCI receptacle: at least one 12 VDC rechargeable battery located inside said battery storage cavity; an inverter configured to convert 12 VDC into 110 VAC, said inverter connected to said rechargeable battery to convert 12 VDC current into 110 VAC, said inverter; a control panel or set of switches electrically connected to said shredder, to said inverter and to said GFCI receptacle, said control panel or set of switches are configured to allow an operator to select the source of electricity either from said GFCI receptacle when said main cable is connected to an external 110 VAC female plug or from said inverter when connected to said rechargeable battery; and a ground roller ball attached to the floor of the housing and configured to contact a surface under the housing when, the portable shredding unit is placed onto the surface said ground roller ball electrically connected to the ground wire of said GFCI receptacle.

Aspects of the present disclosure include devices, systems, methods, and control systems for processing waste into usable products, such as fuel stock, soil additives, and usable byproducts. Various system components may include: 1) a material loading area; 2) a pre-shredder; 3) a magnet based separator; 4) an eddy current separator; 5) additional sorting devices, such as a ballistic separator and/or an optical separator; 6) a mechanical pulverizer, such as a vertical shaft impactor (VSI); 7) a moisture separation device, such as a cyclone; 8) a compressor, such as a ram baler; 9) a packager, such as a bale wrapper; 10) analyzers, such as for moisture and caloric data analysis; 11) a thermal pressure chamber, such as a thermal screw; and 12) a control system to control operation of the system.