A single drive dual hopper conveyor system is presented having a center conveyor system and a pair of side conveyor systems that are connected to one another. A single motor is connected to the center conveyor system and drives movement of a belt within the center conveyor system. The connection of the center conveyor system to the side conveyor system causes the belts of the side conveyor systems to be simultaneously driven as the belt of the center conveyor system is driven. This arrangement eliminates the need for multiple motors. A guide at the center of the belts is configured to guide the belts through the center of the housings and prevent the buildup of grain within a cut-out section of the flights of the belt that is needed to allow access to the links of the belts to facilitate driving of the belts.

A single drive dual hopper conveyor system is presented having a center conveyor system and a pair of side conveyor systems that are connected to one another. A single motor is connected to the center conveyor system and drives movement of a belt within the center conveyor system. The connection of the center conveyor system to the side conveyor system causes the belts of the side conveyor systems to be simultaneously driven as the belt of the center conveyor system is driven. This arrangement eliminates the need for multiple motors. A guide at the center of the belts is configured to guide the belts through the center of the housings and prevent the buildup of grain within a cut-out section of the flights of the belt that is needed to allow access to the links of the belts to facilitate driving of the belts.

A single drive dual hopper conveyor system is presented having a center conveyor system and a pair of side conveyor systems that are connected to one another. A single motor is connected to the center conveyor system and drives movement of a belt within the center conveyor system. The connection of the center conveyor system to the side conveyor system causes the belts of the side conveyor systems to be simultaneously driven as the belt of the center conveyor system is driven. This arrangement eliminates the need for multiple motors. A guide at the center of the belts is configured to guide the belts through the center of the housings and prevent the buildup of grain within a cut-out section of the flights of the belt that is needed to allow access to the links of the belts to facilitate driving of the belts.

A single drive dual hopper conveyor system is presented having a center conveyor system and a pair of side conveyor systems that are connected to one another. A single motor is connected to the center conveyor system and drives movement of a belt within the center conveyor system. The connection of the center conveyor system to the side conveyor system causes the belts of the side conveyor systems to be simultaneously driven as the belt of the center conveyor system is driven. This arrangement eliminates the need for multiple motors. A guide at the center of the belts is configured to guide the belts through the center of the housings and prevent the buildup of grain within a cut-out section of the flights of the belt that is needed to allow access to the links of the belts to facilitate driving of the belts.

A conveyor pan is provided for supporting a portion of a mining conveyor extending along a mine face and positioned between the mine face and a goaf. The conveyor pan includes a deck, a toe, and a heel. The deck includes a first side configured to be positioned proximate the mine face and a second side configured to be positioned proximate the goaf. The toe is positioned adjacent the first side of the deck, and includes a toe contact surface defining a toe surface area. The heel is positioned adjacent the second side of the deck, and includes a lug and a heel contact surface. The lug is configured to be coupled to an advancement mechanism. The heel contact surface defines a heel surface area greater than the toe surface area.

A conveyor pan is provided for supporting a portion of a mining conveyor extending along a mine face and positioned between the mine face and a goaf. The conveyor pan includes a deck, a toe, and a heel. The deck includes a first side configured to be positioned proximate the mine face and a second side configured to be positioned proximate the goaf. The toe is positioned adjacent the first side of the deck, and includes a toe contact surface defining a toe surface area. The heel is positioned adjacent the second side of the deck, and includes a lug and a heel contact surface. The lug is configured to be coupled to an advancement mechanism. The heel contact surface defines a heel surface area greater than the toe surface area.

Methods, systems, brackets, and/or the like are provided. In some embodiments, a multi-connection bracket (MCB) includes a bracket configured to connect a first rail section and a second rail section, wherein the bracket has one or more bracket recesses configured to receive one or more fasteners; and a grounding pad having a pad recess and a plurality of teeth, wherein the pad recess is aligned with at least one of the one or more bracket recesses, wherein the grounding pad is configured to receive the one or more fasteners such that the grounding pad is operably attached to the first rail section or the section rail section, and wherein the grounding pad is configured to deform when operably attached to the first rail section or the second rail section such that the plurality of teeth remove a coating of the first rail section or the second rail section.