Method of handling proppant at a well site using a plurality of modular proppant containers in which first and second modular proppant container in a filled state are removed from delivery transport vehicles and transferred to first and second cradle positions on a support structure using one or more heavy-duty handlers. Proppant is discharged by gravity feed from the outlet of the first and second modular proppant containers and directed to a hopper until the modular proppant containers are in an empty state.

Method of handling proppant at a well site using a plurality of modular proppant containers in which first and second modular proppant container in a filled state are removed from delivery transport vehicles and transferred to first and second cradle positions on a support structure using one or more heavy-duty handlers. Proppant is discharged by gravity feed from the outlet of the first and second modular proppant containers and directed to a hopper until the modular proppant containers are in an empty state.

A kit for forming a hopper bottom of a particulate material storage container comprises a generally conical lower section having a tapering diameter from a first end to the second end such that the second end is sized diametrically smaller, and a plurality of arcuate cone segments each defining an inclined concavely curved wall following a generally circular curvature, all of which can collectively form a hopper cone. The arcuate cone segments are connected in an annulus in which the walls of the arcuate cone segments collectively form a generally conical second cone section having a tapering diameter from one end to an opposite end which has a diameter substantially equal to that of the second end of the first cone section. Afterwards, the opposite end of the formed second cone section is connected to the first end of the first cone section so as to form the hopper cone.

The invention relates to a feed hopper for a material processing device, in particular for a crusher (10), having two side walls (21) and a rear wall of the hopper (22), wherein the side walls (21) are directly or indirectly coupled to a machine support(12.1) in a swiveling manner and can be converted from a set-up work position to a folded-down transport position and back, wherein a feed area is formed between the side walls (21), and wherein at least one of the side walls (21) is supported relative to the machine support (12.1) in the set-up work position by means of a supporting device (30). To provide an effective securing of the side wall in the unfolded work position for such a feed hopper featuring a minimum of cost and effort in parts and assembly, provision in made in accordance with the invention for the support device (30) to have a support lever (31), which in the work position is supported directly or indirectly in relation to the machine support (12.1) by means of a detachable form-fit connection, wherein the form-fit connection prevents the side wall (21) from folding down, and in that the support lever (31) projects into the feed area in the folded-down transport position. In this way, a space-saving design is also achieved in the folded-down transport position.

An expandable and collapsible grain bin is provided comprising at least two telescoping cylindrical sections adapted to interlock with one another when the grain bin is in an expanded position; a base member attached to the bottom most cylindrical section; and a bin cover for enclosing the grain bin, said bin cover adapted to be in a raised position when the grain bin is in the expanded position and in a lowered position when the grain bin is in a collapsed position.

A bulk loader system is disclosed that may include a conveyor unit in connection with a fuel-powered engine powering a hydraulic motor. The hydraulic motor may be used to operate the conveyor unit. The system may be configured to function while being mounted on a bed of a truck or be operated as a stand-alone unit. The unit may be sized such that an operator can stand on the deck of the truck along with the unit. The fuel-hydraulic powered motor can enable the conveyor unit to operate at variable speeds. The conveyor unit can be adjustable to facilitate controlling the direction of the material being transported via the conveyor. Some embodiments can include operating the hydraulics of the motor from the Power Take-Off (PTO) of the truck. Some embodiments can facilitate operation of the system in a hot or other harsh environment.

A bulk loader system is disclosed that may include a conveyor unit in connection with a fuel-powered engine powering a hydraulic motor. The hydraulic motor may be used to operate the conveyor unit. The system may be configured to function while being mounted on a bed of a truck or be operated as a stand-alone unit. The unit may be sized such that an operator can stand on the deck of the truck along with the unit. The fuel-hydraulic powered motor can enable the conveyor unit to operate at variable speeds. The conveyor unit can be adjustable to facilitate controlling the direction of the material being transported via the conveyor. Some embodiments can include operating the hydraulics of the motor from the Power Take-Off (PTO) of the truck. Some embodiments can facilitate operation of the system in a hot or other harsh environment.

An apparatus to support a proppant container includes a frame to receive and support the proppant container. The frame has a top surface that receives and positions the proppant container in an elevated position. The apparatus also includes a box guide assembly positioned on the top surface a box guide assembly connected to the top surface of the frame for defining a cradle section having four corners. The box guide assembly including a box guide positioned at each of the corners. Each box guide has a corner member extending upwardly from the top surface along a peripheral edge of the frame and a guide member extending adjacent the corner member. The guide member include an inclined face for aligning the proppant container in the cradle section. The box guide assembly guides the proppant container into the cradle section when loaded onto the frame in the elevated position.

An apparatus to support a proppant container includes a frame to receive and support the proppant container. The frame has a top surface that receives and positions the proppant container in an elevated position. The apparatus also includes a box guide assembly positioned on the top surface a box guide assembly connected to the top surface of the frame for defining a cradle section having four corners. The box guide assembly including a box guide positioned at each of the corners. Each box guide has a corner member extending upwardly from the top surface along a peripheral edge of the frame and a guide member extending adjacent the corner member. The guide member include an inclined face for aligning the proppant container in the cradle section. The box guide assembly guides the proppant container into the cradle section when loaded onto the frame in the elevated position.

A feed distribution assembly for transporting and dispensing feed includes a trailer and a silo. The silo is coupled to a bed of the trailer and is configured to position feed. The trailer is configured to couple to a vehicle to transport the feed to a desired location. An auger is coupled to a bottom of the silo. The auger is configured to selectively convey the feed from the silo to dispense the feed at the desired location.