A secondary seal system for a storage tank having a floating roof includes a seal compression plate attached to and extending upwards at an oblique angle from the floating roof, extending around the circumference of the floating roof; a seal element attached to the compression plate for sealing between the compression plate and an inner surface of the storage tank; a plurality of anti-rollover plates attached to and extending upwards from the seal compression plate; and a plurality of anti-rollover braces attached to a major surface of the seal compression plate.

The invention relates to a storage facility for the storage of highly volatile hydrocarbons, comprising at least one vertical round tank (I) which is equipped with a floating cover (5), covering the liquid surface, in the form of a floating roof or a floating ceiling, wherein an annular space (8) formed between the cover (5) and tank wall (3) is sealed by means of flexible sealing elements (9) and wherein fittings (12, 13) for automatic control of overpressures and under pressures in the space (4) under the cover (5) are integrated into the cover (5). The fittings (12, 13) of the at least one round tank (I) are connected to a vapour line (14), the upper end of which is led out of the tank (1) and is in turn connected to a separate vapour expansion tank (15), wherein the round tank (I) and the vapour compensation tank (15) form a closed system.

The invention relates to a storage facility for the storage of highly volatile hydrocarbons, comprising at least one vertical round tank (I) which is equipped with a floating cover (5), covering the liquid surface, in the form of a floating roof or a floating ceiling, wherein an annular space (8) formed between the cover (5) and tank wall (3) is sealed by means of flexible sealing elements (9) and wherein fittings (12, 13) for automatic control of overpressures and under pressures in the space (4) under the cover (5) are integrated into the cover (5). The fittings (12, 13) of the at least one round tank (I) are connected to a vapour line (14), the upper end of which is led out of the tank (1) and is in turn connected to a separate vapour expansion tank (15), wherein the round tank (I) and the vapour compensation tank (15) form a closed system.

An automatic aeration device includes a first floating roof, a second floating roof and a movable valve. The first floating roof has a through hole and a first enclosure. The second floating roof is disposed in the through hole and has a second enclosure. The movable valve is disposed above the first floating roof and the second floating roof and has a plate which has an outer wall and an inner wall. The outer wall is mounted in the first enclosure and has a plurality of first vent holes. The inner wall is mounted in the second enclosure and has a plurality of second vent holes. The automatic aeration device further includes a plurality of balls mounted between the first enclosure and the outer wall, and mounted between the second enclosure and the inner wall.

An automatic aeration device includes a first floating roof, a second floating roof and a movable valve. The first floating roof has a through hole and a first enclosure. The second floating roof is disposed in the through hole and has a second enclosure. The movable valve is disposed above the first floating roof and the second floating roof and has a plate which has an outer wall and an inner wall. The outer wall is mounted in the first enclosure and has a plurality of first vent holes. The inner wall is mounted in the second enclosure and has a plurality of second vent holes. The automatic aeration device further includes a plurality of balls mounted between the first enclosure and the outer wall, and mounted between the second enclosure and the inner wall.

A polyethylene floating roof design equipped with height adjustable bases. Allowing full discharge of the tank and having people enter the tank and the space below the roof in case of adjusting the bases in maintenance mode for dredging and repairs.

A fermentation method and system which includes providing juice to be fermented into a container. The juice having a cap that is a collection of solid components of grapes. The cap has a permeable consistency and floats in the juice. The method includes moving a portion of the juice from below the cap upward into contact with the cap.

Various embodiments generally relate to robotics and more specifically to tank seal inspections. In some embodiments, the robotic inspection device comprising a power supply, a body, a drive system, a camera, a navigational system, and/or one or more sensors. The drive system may include one or more surface engaging drivers to propel the robotic inspection device along a surface of a tank. The camera can be housed within the body to capture images and/or video of a seal. The navigational system can compute a route (or receive commands that route) and send commands to the drive system to navigate the robotic inspection device along the surface of the tank allowing the camera to capture the images or video of the seal. Some embodiments may use an artificial intelligence or machine learning engine to review the images or video of the seal and identify potential problems.

A peripheral sealing assembly for connection with a buoyant panel unit usable in a liquid storage tank includes a fixing frame, an enclosure, and a buffer pipes. The fixing frame connects the buoyant panel unit. The enclosure is fixed to the fixing frame to sealingly contact an inner surrounding wall of the liquid storage tank. The enclosure defines a looped receiving space between the inner surrounding wall and the buoyant panel unit. The buffer pipes are inserted into the looped receiving space. Each buffer pipe is hollow, extends along the looped receiving space and has a lengthwise outer peripheral surface fixed to the lengthwise outer peripheral surfaces of two adjacent other buffer pipes.

A peripheral sealing assembly for connection with a buoyant panel unit usable in a liquid storage tank includes a fixing frame, an enclosure, and a buffer pipes. The fixing frame connects the buoyant panel unit. The enclosure is fixed to the fixing frame to sealingly contact an inner surrounding wall of the liquid storage tank. The enclosure defines a looped receiving space between the inner surrounding wall and the buoyant panel unit. The buffer pipes are inserted into the looped receiving space. Each buffer pipe is hollow, extends along the looped receiving space and has a lengthwise outer peripheral surface fixed to the lengthwise outer peripheral surfaces of two adjacent other buffer pipes.