A spreader, in particular for winter service vehicles, for spreading out solid spreading materials includes a spreading-material container for receiving the solid spreading materials to be spread out, and at least one liquid tank arranged within the spreading-material container and having an at least partly flexible sheath and variable volume for receiving liquid. The spreader furthermore comprises a conveying device in a floor surface of the spreading-material container for conveying the spreading materials out of the spreading-material container. The floor surface of the spreading-material container is horizontal or almost horizontal, with the at least one liquid tank being arranged on or above the floor surface such that, upon an at least partial filling of the liquid tank, there is formed a sliding surface for the solid spreading materials to be spread out that is inclined toward the conveying device relative to the floor surface.

A tank assembly for receiving liquids comprises a tank body. The tank body includes a tank wall defining an enclosed tank cavity. The tank body also includes a manhole lid attached to the tank wall and movable from a closed position covering a manhole in the tank body to an open position uncovering the manhole. A liner includes a flexible liner wall defining an enclosed liner cavity. An opening is formed in the liner wall to permit liquid to be introduced into the liner cavity. The liner also includes a fitting secured to the liner wall at the opening in the liner wall. A first end of a hose is attached to the fitting for conducting fluid to the liner cavity. A valve is attached to a second end of the hose. The valve and the second end of the hose are releasably attached to the manhole lid.

A tank assembly for receiving liquids comprises a tank body. The tank body includes a tank wall defining an enclosed tank cavity. The tank body also includes a manhole lid attached to the tank wall and movable from a closed position covering a manhole in the tank body to an open position uncovering the manhole. A liner includes a flexible liner wall defining an enclosed liner cavity. An opening is formed in the liner wall to permit liquid to be introduced into the liner cavity. The liner also includes a fitting secured to the liner wall at the opening in the liner wall. A first end of a hose is attached to the fitting for conducting fluid to the liner cavity. A valve is attached to a second end of the hose. The valve and the second end of the hose are releasably attached to the manhole lid.

A flexible liner system for a silo receiving and storing granular materials, in which the flexible liner system includes a first flexible inflate liner and a second flexible inflate liner placed in the silo and aligned respectively against a silo wall and a silo floor. The first inflate liner and the second inflate liner are separated from each other by a central trough that extends completely across or substantially completely across the silo floor. The flexible liner system includes a conveyor assembly that inflates each inflate liner to push the granular material toward the central trough and aerates the granular material stored in the silo. The flexible liner system further includes a liner return system that allows each inflate liner to be brought back against the wall and the floor of the silo during deflation.

A flexible liner system for a silo receiving and storing granular materials, in which the flexible liner system includes a first flexible inflate liner and a second flexible inflate liner placed in the silo and aligned respectively against a silo wall and a silo floor. The first inflate liner and the second inflate liner are separated from each other by a central trough that extends completely across or substantially completely across the silo floor. The flexible liner system includes a conveyor assembly that inflates each inflate liner to push the granular material toward the central trough and aerates the granular material stored in the silo. The flexible liner system further includes a liner return system that allows each inflate liner to be brought back against the wall and the floor of the silo during deflation.

A flexible tank is used to transport bulk liquids or semi-liquid materials inside of a multi-modal shipping container. It has water proof inner layers and an outer layer, which are formed and welded together to have seams at both ends of the flexible tank. A discharge valve is provided at one end of the flexible tank and an additional piece of material, referred to as a cape, is attached at the other end of the flexible tank. The flexitable tank is situated in the container so that the end with the discharge valve is at the container opening and the end with the attached cape is at the rear of the container. The cape can be used by equipment positionable at the opening of the container to completely discharge the bulk liquids or semi-liquid materials from the flexible tank by pulling and winding up the cape and the layers of the flexible tank from the rear of the container.

A fuel tank has a welded member that is welded inside a fuel tank body. The welded member includes a welded face that is welded on at least one of a first tank face and a second tank face which faces the first tank face, of the fuel tank body, and wherein the welded face includes a facing side in a concave shape that faces a given point determined based on a displacement of distance between the first tank face and the second tank face when the fuel tank body receives an internal pressure.

Using a subsea fluid storage system 1 comprising a soft bladder (20) disposed within a pressure balanced reservoir (10), a rotatable piston (30) disposed at least partially within the pressure balanced reservoir where a top of the soft bladder is in communication with the rotatable piston, and a piston rotator (50) operative to rotate and twist the rotatable piston as the rotatable piston travels along a predetermined axis within the pressure balanced reservoir, a predictable and repeatable collapse of the soft bladder may be obtained by allowing the rotating piston (30) to cooperatively travel about the piston rotator (50) to twist the soft bladder (20) as the rotating piston moves along the predetermined axis in such a manner as to collapse the bladder inward, thereby emptying the bladder of fluid within the bladder. The rotation of the piston pulls the soft bladder away from an interior of the pressure balanced reservoir, thereby preventing binding or pinching of the bladder with respect to the interior of the pressure balanced reservoir. In configurations, fluid is allowed to enter the pressure balanced reservoir via a valve (54) until a balance is achieved between an interior and an exterior of the pressure balanced reservoir.

A dispensing system for dispensing an associated substantially viscous product includes a dispensing system housing and a first container. The first container is disposed within the dispensing system housing and has an elastically deformable wall defining a changeable volume for containing the associated product. The elastically deformable wall is expandable between an unexpanded state and an expanded state. The first container includes an outlet through which the associated product is expelled. Potential energy stored in the deformable wall in the expanded state is operable to expel the associated product from the first container through the outlet. The dispensing system includes a selectively engage-able valve operatively fluidly connected to the outlet for controlling the expulsion of a predetermined amount of the associated product from the outlet. An actuator is operatively coupled to the valve to selectively engage the valve.

A tilt-less liner apparatus and system for unloading bulk cargo from a container liner using a first layer on the container liner floor having a friction reducing top layer and a friction enhancing bottom layer to secure first layer against movement. A second layer of flexible high strength material folded in over lapping multiple pre-folded sections from at least two to eight folded stacked layers are used to cover the friction reducing top first layer. The second layer is connected to a coiling means and motor for coiling up and removing the second layer from the container over the friction reducing top layer of the first layer and the bulk cargo comes out with the second layer into a hopper provided with means for bulk product distribution. Vibrators, depth measuring devices and speed controls are provided to control bulk cargo unloading and prevent blockage build up.