A shredding assembly for a grinder pump includes a stationary shredding ring mounted to an inlet of the pump, and a cutting device rotatable about an axial direction and fixed to a shaft of the pump. The shredding ring includes a top face, a bottom face, and a central opening extending from the top face to the bottom face and delimited in a radial direction by an inner periphery. Slots extending in the axial direction are formed in the inner periphery. The cutting device is positioned in the central opening of the shredding ring, and includes a front face and a back face. The front face includes a plurality of first cutting members extending in the axial direction and facing the slots. The back face includes a second cutting member projecting beyond the central opening with respect to the radial direction.

Provided is a hair cutting assembly. The hair cutting assembly includes at least one first shearing wheel, first transmission shaft that drives the first shearing wheel to rotate, at least one second shearing wheel and second transmission shaft that drives the second shearing wheel to rotate. Opposite end surfaces of each first shearing wheel and the corresponding second shearing wheel are attached to each other. The first cutting blades, formed by intersecting end surface of the first shearing wheel with side wall, and the second cutting blades, formed by intersecting end surface of the second shearing wheel with side wall, oppositely move in a feed direction, such that long and thin linear sundries such as hairs and fabrics can be continuously shorn. A floor drain with the hair cutting assembly is also provided.

Machines, processes and methods in relation to processing of waste, in particular food waste or organic waste are provided. Some embodiments of described machines, processes and methods include a drum to receive waste, mixing blades to process waste, a source of air that is rich in reactive oxygen species, an air flow system comprising a heater to circulate air through the drum, and sensors provided in the machine to monitor operating parameters. A control system is configured to control operation of the machine.

Systems and methods for rendering cannabis-related waste materials are provided. The method may include inserting a plurality of cannabis-related waste materials into, for example, a mobile rendering vehicle. The method may further include physically altering the cannabis-related waste materials such that the cannabis-related waste materials are unrecognizable and unusable. The insertion of the cannabis-related waste materials into the mobile rendering vehicle may be recorded and/or the physical alteration (e.g., pulverization) of the cannabis-related waste materials may be recorded via one or more cameras disposed on the mobile rendering vehicle to verify proper insertion and/or alteration of the cannabis-related waste materials.

A waste disposer comprising a primary dehydrating chamber, a grinding device, a secondary dehydrating chamber, and a storage chamber. The primary dehydrating chamber is adapted to allow waste to be heated therein to partly dehydrate the waste. The primary dehydrating chamber has: a first waste inlet for receiving the waste, a first vapor outlet for exhausting vapor from the waste, a drainage outlet for draining free liquid from the waste, and a first waste outlet for outputting the partly dehydrated waste. The grinding device is adapted to receive the waste from the first waste outlet and grind the waste to reduce the size thereof. The secondary dehydrating chamber is adapted to allow the ground waste to be heated therein to further dehydrate the waste. The secondary dehydrating chamber has a second waste inlet for receiving the ground waste, a second vapor outlet for exhausting vapor from the waste, and a second waste outlet for outputting the further dehydrated waste. The storage chamber is adapted to receive the waste from the second waste outlet and store the waste in the storage chamber.

Food waste disposer systems and related systems for coupling food waste disposer systems to electrical power sources, and related coupling and configuration methods, are disclosed herein. In at least one example embodiment, a food waste disposer system includes a motor, a switch module, a housing, and an appliance inlet power cord connection structure supported at least indirectly upon the housing, where the connection structure is either connected to or integrally formed with the switch module. Further, the food waste disposer system also includes a power cord including a first end with a first plug and a second end with a second plug, where the first plug is configured to be coupled to the connection structure. Additionally, the food waste disposer includes an adapter or first lead wires that are coupled at least indirectly to the connection structure.

A food recycler includes a base, at least one air intake opening, a gearbox, and a motor. An airflow component is on top of the motor. A fan is configured on the airflow component and a filter is positioned at an output port of the airflow component. A bucket receptacle is configured on the gearbox. The fan and the filter are configured adjacent to an upper portion of the bucket receptacle. A casing has a lower rim complimentary to a base rim. The casing has an interior volume complimentary to a fan module and an interior volume complimentary to an air filter module. A control switch and lid latch are configured in the casing and next to each other. A lid is hinged to the casing such that air flows from a bucket through the lid to the fan and back from the filter to the lid and out an exhaust vent in the lid.

A food recycler can include a housing defining an interior and an access opening to the interior. A mixing bin can be located within the interior and can have an inlet and an outlet. The food recycler can further include an output bin, the output bin having an inlet. The outlet of the mixing bin can couple or connect to the inlet of the output bin. The food recycler further has a transfer assembly for transferring food waste from the mixing bin to the output bin. The transfer assembly includes a chute mounted to the housing and operably coupling the first outlet of the mixing bin to the second inlet of the output bin, and at least one vibration damper positioned between the housing and the chute configured to allow flexibility of the chute to vibrate relative to the housing.

The present invention describes a Food Waste Recycling system 10 consisting of four major units, crushing, screw conveyor for squeezing, controlled heating for curing and activated carbon filter for deodorization. The present invention uses slow moving crusher blades 28 powered by a slow rotating motor 26 to crush all types of food waste including bones. This increases the surface area for uniform drying. The same motor can be used to rotate the squeezer 30 placed below the crusher. Output of the squeezing unit is fed to the curing unit; containing the stirrer blades 48 and the heater 32 to get the nutrient rich product that can be used as a soil amendment, animal feed or for gardening purpose. By using this device food waste, kitchen waste, herb residues, fruit and vegetable waste, leaves, meat, cereals and even bones can be recycled. The device has advantages of being simple in structure, easy to operate, cost-effective, energy efficient and have short treatment cycle.

A food waste disposer includes a food conveying section, a grind and discharge section and a motor section used for driving the grind and discharge section to execute a grinding process. The motor section includes a universal motor, the universal motor includes a control device for controlling the output of the universal motor, and the control device includes a rectifier bridge circuit module for converting an AC power signal into a DC power signal.