Embodiments of the present invention pertain to a plant trimming apparatus and method having a central processing unit that provides enhanced capabilities as a result of integrating robotic features, automations, artificial intelligence, queuing, fault control, automatic transport, scalability, safety measures, smaller footprint, and other computerized functions, along with a creative business model. In design of this invention the following high-level requirements were achieved: scalable for small, medium, and large businesses; safer than other machines in the market; sanitation consideration; simplicity in maintenance, and automated functions to reduce the need for labor (e.g., integration of robotics, AI, and/or other computerized systems).

Embodiments according to the present invention relate to an apparatus and method for plant transportation using a smart conveyor. Embodiments of the present invention provide enhanced capabilities as a result of integrating robotic features, automations, artificial intelligence, queuing, fault control, automatic transport, scalability, safety measures, smaller footprint, and other computerized functions, along with a creative business model. In design of this invention the following high-level requirements were achieved: scalable for small, medium, and large businesses; safer than other machines in the market; sanitation consideration; simplicity in maintenance, and automated functions to reduce the need for labor (e.g., integration of robotics, AI, and/or other computerized systems).

A discharging device for mills, comprising: a conduit (10), structured so as to be connected to a discharge opening (3) of a mill (1); a bend (11) disposed along the conduit (10), which defines a curve of the conduit (10); a regulating device (12) associated to the bend (11) and predisposed for varying the position of the bend (11) so as to vary at least a height thereof.

A lead needle and lead slime separator for treating thin lead grid of waste lead-acid storage battery, includes: a barrel body, corrosion-resistant and wear-resistant balls, a feed device, a bracket device, a discharge device and a driver. A feed hole is arranged at one end of the barrel body, a discharge port is arranged at the other end of the barrel body. The feed device is mounted at the feed hole, and the discharge device is mounted at the discharge hole. The bracket device is connected to the barrel body, the driver is connected to the barrel body. The corrosion-resistant and wear-resistant balls are arranged in the barrel body. The separator can make the thin lead grid separation complete, clean and impurity-free. It does not need to be melted at high temperature in the melting furnace.

Embodiments of the present invention pertain to an apparatus and method for automatic blade and razor for use in plant trimming. Embodiments of the present invention provides enhanced capabilities as a result of integrating robotic features, automations, artificial intelligence, queuing, fault control, automatic transport, scalability, safety measures, smaller footprint, and other computerized functions, along with a creative business model. In design of this invention the following high-level requirements were achieved: scalable for small, medium, and large businesses; safer than other machines in the market; sanitation consideration; simplicity in maintenance, and automated functions to reduce the need for labor (e.g., integration of robotics, AI, and/or other computerized systems).

Embodiments according to the present invention relate to a modular plant trimming system and method that provides enhanced capabilities as a result of integrating robotic features, automations, artificial intelligence, queuing, fault control, automatic transport, scalability, safety measures, smaller footprint, and other computerized functions, along with a creative business model. In design of this invention the following high-level requirements were achieved: scalable for small, medium, and large businesses; safer than other machines in the market; sanitation consideration; simplicity in maintenance, and automated functions to reduce the need for labor (e.g., integration of robotics, AI, and/or other computerized systems).

Methods for cost effectively transforming lower quality silica sands into higher quality silica sands for use as proppants in fracking operations involving subterranean hydrocarbon formations. A process of exposing silica sand proppants to locally-sourced electromagnetic radiation, and systems therefor, are disclosed and shown to increase the performance of those silica sands as proppants in hydrocarbon formation fracturing operations.

Methods for cost effectively transforming lower quality silica sands into higher quality silica sands having increased crush resistance for use as proppants in fracturing operations involving subterranean hydrocarbon formations. One or more of an attrition process, a microwaving process and a tumbling process are disclosed and shown to be applied to silica sands having inferior physical properties in order to increase the performance of those silica sands as proppants in hydrocarbon formation fracturing operations.

Methods for cost effectively transforming lower quality silica sands into higher quality silica sands for use as proppants in fracking operations involving subterranean hydrocarbon formations. A process of exposing silica sand proppants to locally-sourced electromagnetic radiation, and systems therefor, are disclosed and shown to increase the performance of those silica sands as proppants in hydrocarbon formation fracturing operations.

An open-ended grinding mill (1) includes a drum (2) including a cylindrical shell (3), wherein the longitudinal axis (4) of the drum is arranged in a substantially horizontal position in a use position of the grinding mill (1). The drum (2) includes a first end (5) at the feed end of the shell and a second end (6) at the discharge end of the shell. The grinding mill further includes a bearing (8) supporting the drum at the second end, and a support structure (9) to connect the drum (2) to the bearing (8). The support structure is configured to provide a wall external to the shell, whereby the shell and the support structure provide a double-wall structure separating the bearing from the inside of the drum.