Systems and methods are provided for safely and efficiently transporting granular material. In one embodiment, a container for granular material is provided. The container can have a top plate and a bottom plate that are coupled to one another via one or more high-strength fabric sleeves. The bottom plate can include a discharge valve for discharging the granular material in the container. The container can also include a discharge bladder that, when inflated, biases granular material within the container toward the discharge valve. The container can also include at least one barrier positioned proximate the discharge valve such that the barrier prevents at least a portion of the discharge bladder from entering the discharge valve. The barrier can allow sand or other granular material to pass through the barrier and exit through the discharge valve.

A storage vessel assembly for storing chemical includes a storage vessel, a frame for housing the storage vessel, an agitation device disposed in the storage vessel, a temperature control system coupled to the storage vessel, and a controller configured to operate the agitation device and the temperature control system.

A storage vessel assembly for storing chemical includes a storage vessel, a frame for housing the storage vessel, an agitation device disposed in the storage vessel, a temperature control system coupled to the storage vessel, and a controller configured to operate the agitation device and the temperature control system.

A frame delimits an inside space and includes a peripherally closed side wall and two transverse openings or one transverse opening and a transverse end wall. It is capable of allowing the airtight engagement of the open free edge of a side wall in film form of a receptacle that is at least partially deformable. It is specially designed for the creation of a 3D container. The frame is also able to act as a support for at least one functional port or attachment port of a functional element. Its axial size is adequate for delimiting a space of a size that is at least equal to the axial dimension of the functional element, so that the latter can be completely housed within the inside space.

The present invention is directed to a new concept for a large-scale high-pressure Honeycomb Set Tank in an ISO container and for its manufacturing facilities. A process for manufacturing a plurality of honeycomb cells with a high degree of accuracy is also provided.

The present invention is directed to a new concept for a large-scale high-pressure Honeycomb Set Tank in an ISO container and for its manufacturing facilities. A process for manufacturing a plurality of honeycomb cells with a high degree of accuracy is also provided.

A canopy for a compressor or generator installation comprising a chassis (2) witha base plate (3) comprising a body with a mounting surface bounded by a polygonal peripheral edge (4); anda mounting frame (5) containing this base plate (3) and going around the peripheral edge (4); whereby the canopy (1) further comprises a number of corner stays (6), whereby each corner stay (6) is provided with a mounting end which is configured to be mounted onto the chassis (2), whereby at each corner of the peripheral edge (4), at least one corner stay (6) is mounted with its mounting end onto the chassis (2), whereby each corner stay (6) in a mounted state extends from the mounting surface of the base plate (3) in a direction essentially perpendicular to the mounting surface and outwards from the body of the base plate (3), and whereby each corner stay (6) in a mounted state has a free end which is opposite to the mounting end of this corner stay (6) and which is not mounted onto the mounting surface; and whereby the canopy (1) further comprises at least one roof panel (9), characterised in that at each one corner of the peripheral edge (4), the free end of the at least one corner stay (6) is configured to be connected by means of at least one lateral beam (10) to the free end of the at least one corner stay (6) which is mounted at a corner adjacent to said one corner; and that the canopy (1) further comprises a number of lateral beams (10) such that, at each one corner of the peripheral edge (4), the free end of the at least one corner stay (6) at said one corner is connected to the free end of the at least one corner stay (6) which is mounted at a corner adjacent to said one corner.

A canopy for a compressor or generator installation comprising a chassis (2) witha base plate (3) comprising a body with a mounting surface bounded by a polygonal peripheral edge (4); anda mounting frame (5) containing this base plate (3) and going around the peripheral edge (4); whereby the canopy (1) further comprises a number of corner stays (6), whereby each corner stay (6) is provided with a mounting end which is configured to be mounted onto the chassis (2), whereby at each corner of the peripheral edge (4), at least one corner stay (6) is mounted with its mounting end onto the chassis (2), whereby each corner stay (6) in a mounted state extends from the mounting surface of the base plate (3) in a direction essentially perpendicular to the mounting surface and outwards from the body of the base plate (3), and whereby each corner stay (6) in a mounted state has a free end which is opposite to the mounting end of this corner stay (6) and which is not mounted onto the mounting surface; and whereby the canopy (1) further comprises at least one roof panel (9), characterised in that at each one corner of the peripheral edge (4), the free end of the at least one corner stay (6) is configured to be connected by means of at least one lateral beam (10) to the free end of the at least one corner stay (6) which is mounted at a corner adjacent to said one corner; and that the canopy (1) further comprises a number of lateral beams (10) such that, at each one corner of the peripheral edge (4), the free end of the at least one corner stay (6) at said one corner is connected to the free end of the at least one corner stay (6) which is mounted at a corner adjacent to said one corner.

Systems and methods for efficiently managing bulk material are provided. The disclosure is directed to a portable support structure used to receive one or more portable containers of bulk material and output bulk material from the containers directly into the blender hopper. The portable support structure may include a frame for receiving and holding the one or more portable bulk material containers in an elevated position proximate the blender hopper, as well as one or more gravity feed outlets for routing the bulk material from the containers directly into the blender hopper. In some embodiments, the portable support structure may be transported to the well site on a trailer, unloaded from the trailer, and positioned proximate the blender unit. In other embodiments, the portable support structure may be a mobile support structure that is integrated into a trailer unit.

Systems and methods for efficiently managing bulk material are provided. The disclosure is directed to a portable support structure used to receive one or more portable containers of bulk material and output bulk material from the containers directly into the blender hopper. The portable support structure may include a frame for receiving and holding the one or more portable bulk material containers in an elevated position proximate the blender hopper, as well as one or more gravity feed outlets for routing the bulk material from the containers directly into the blender hopper. In some embodiments, the portable support structure may be transported to the well site on a trailer, unloaded from the trailer, and positioned proximate the blender unit. In other embodiments, the portable support structure may be a mobile support structure that is integrated into a trailer unit.