Systems and methods for conveying non-dry frac proppant are described herein. The system generally includes at least one hopper having at least one moisture sensor, a slide gate that is fluidly connected to the at least one hopper, a conveyor assembly having at least one conveyor belt configured to convey the non-dry frac proppant from the at least one hopper to a blender, and at least one load sensor, and a control device configured to regulate a discharge rate of the non-dry frac proppant and a load rate of the non-dry frac proppant. The method generally includes providing the system at a well site to convey a non-dry frac proppant from a source point the at least one hopper, the conveyor assembly at a discharge rate determined by the control device, and the blender at a load rate determined by the control device.

A sandbag filling system includes a support frame, a driving unit, a conveyor unit, and a hopper chute. The support frame includes a feed gate and an adjustable mount and is configured to receive a material and guide the material to a conveyor belt. The driving unit is arranged in the support frame and includes a motor connected to a drive shaft. The conveyor unit is arranged in the support frame as well and includes a conveyor belt configured to be moved by the driving unit. The hopper chute is arranged below the feed gate of the support frame and located proximal to the conveyor belt.

A sandbag filling system includes a support frame, a driving unit, a conveyor unit, and a hopper chute. The support frame includes a feed gate and an adjustable mount and is configured to receive a material and guide the material to a conveyor belt. The driving unit is arranged in the support frame and includes a motor connected to a drive shaft. The conveyor unit is arranged in the support frame as well and includes a conveyor belt configured to be moved by the driving unit. The hopper chute is arranged below the feed gate of the support frame and located proximal to the conveyor belt.

Described is a system for conveying wet sand. The system includes containers with a slip coating for storing wet sand. Each container includes an outlet formed in a bottom portion to facilitate removal of the wet sand from the container to a hopper. Each hopper has end walls, side walls, and an interior wall extending at an angle from the top to the bottom of the hopper to reduce an area of the outlet. A flow gate over the outlet controls discharge of the wet sand from the hopper onto a conveyor belt of a conveyor system. The hopper also includes a vibration system coupled to its exterior surface for shaking the hopper to assist in releasing sand. A discharge assembly is located at the end of the conveyor system for directing wet sand from the conveyor belt.

A material-conveying system comprising a conveyor for conveying material to a bin and a conveyor positioning system associated with the conveyor. The conveyor positioning system comprises a processor for positioning the conveyor relative to the bin. The conveyor comprises a spout and the bin comprises an opening. The conveyor positioning system positions the spout of the conveyor over the opening of the bin. The conveyor positioning system in one implementation comprises a Global Navigation Satellite System-Real Time Kinematic (GNSS-RTK) positioning system that includes a fixed base station and a GNSS receiver on the conveyor.

A material-conveying system comprising a conveyor for conveying material to a bin and a conveyor positioning system associated with the conveyor. The conveyor positioning system comprises a processor for positioning the conveyor relative to the bin. The conveyor comprises a spout and the bin comprises an opening. The conveyor positioning system positions the spout of the conveyor over the opening of the bin. The conveyor positioning system in one implementation comprises a Global Navigation Satellite System-Real Time Kinematic (GNSS-RTK) positioning system that includes a fixed base station and a GNSS receiver on the conveyor.

The disclosure provides a bulk material unloading system and method. The system includes a bulk material container containing a bulk material and an unloading device. The unloading device is configured to engage the bulk material container and at least partially invert the bulk material container. The method includes engaging a bulk material container containing a bulk material with an unloading device and emptying the bulk material container. Emptying the bulk material into the hopper includes lifting the bulk material container using the unloading device and rotating the bulk material container using the unloading device.

A flowable-material transfer station includes a mobile frame and a conveyor coupled thereto. A hopper mounted on the mobile frame has a side wall with an opening. A chute's loading end is rigidly coupled to the hopper at the side wall opening thereof wherein the chute is in fluid communication with the hopper via the opening. The hopper is hingedly coupled to the mobile frame and the chute's dispensing end is positioned over a first end of the conveyor. A lift mechanism is provided to move the hopper between a lowered position and a raised position. The chute's dispensing end is above the chute's loading end when the hopper is in its lowered position, and is below the chute's loading end when the hopper is in its raised position.

A material-conveying system comprises a main conveyor for conveying material, a swing conveyor for conveying the material to the main conveyor and a processor for controlling a speed of the swing conveyor based on a feedback signal. The feedback signal may be indicative of a speed of the swing conveyor and/or a speed of a main conveyor. The feedback signal may be indicative of material level, belt slippage, flow rate, belt angle and/or material rollback.

A material-conveying system comprises a main conveyor for conveying material, a swing conveyor for conveying the material to the main conveyor and a processor for controlling a speed of the swing conveyor based on a feedback signal. The feedback signal may be indicative of a speed of the swing conveyor and/or a speed of a main conveyor. The feedback signal may be indicative of material level, belt slippage, flow rate, belt angle and/or material rollback.