A floatable frame structure has concatenated frame modules, each formed of columns arranged substantially vertically. Neighboring columns are interconnected by upper and lower tie bars and form module sections. The connections between the tie bars and columns have rotary joints arranged at upper and lower nodes on the columns. At least one horizontal rotation joint is arranged for each column in the connection to an associated tie bar, and at least one spherical rotary joint or elastic rotary joint is arranged for each tie bar. Each module section is provided with elastic tensile elements secured to diagonally opposite upper and lower nodes, nodes lying diagonally opposite each other in the same horizontal plane and in the same frame module being connected by elastic tensile elements. Some columns form containers with submersible portions with positive buoyancy, and adjacent frame modules sharing at least one column.

A universal mounting system for insulated instruments includes a mounting plate which engages openings in mating parts of a self-supporting insulated enclosure. The plate supports the instrument and the enclosure independently and allows all connections to the interior of the enclosure to be made through the plate. The plate is bent to an L-shape, with one leg supported by a support structure and the other leg supporting the instrument and enclosure. A termination of a traced tubing system is housed in an enclosure mounted to an opposite side of the mounting plate. The mounting plate includes a collar, cutouts in mating sections of the enclosure fitting over the collar to mount the enclosure to the mounting plate. Illustratively, the mounting plate includes a mount plate portion connected to a supporting structure, and an instrument plate mounted to the instrument.

The invention relates to a biogas plant for fermenting organic materials and for generating biogas, having a plurality of containers and/or tanks, which form at least one slurry store (7), at least one fermenter container (8) downstream of the slurry store (7), at least one post-fermenter container (9) downstream of the fermenter container (8) and/or at least one final storage container (10) downstream of the fermenter container (8). According to the invention it is provided that the entire functional biogas plant is, as a floating biogas plant, a component of a one-part or of a multi-part connected floating body.

A universal mounting system for insulated instruments includes a mounting plate which engages openings in mating parts of a self-supporting insulated enclosure. The plate supports the instrument and the enclosure independently and allows all connections to the interior of the enclosure to be made through the plate. The plate is bent to an L-shape, with one leg supported by a support structure and the other leg supporting the instrument and enclosure. A termination of a traced tubing system is housed in an enclosure mounted to an opposite side of the mounting plate. The mounting plate includes a collar, cutouts in mating sections of the enclosure fitting over the collar to mount the enclosure to the mounting plate. Illustratively, the mounting plate includes a mount plate portion connected to a supporting structure, and an instrument plate mounted to the instrument.

An offshore facility for producing a liquefied natural gas using an associated gas includes a crude oil production offshore facility having a crude oil processing device for refining crude oil collected from a subsea well to produce oil, and a gas reinjection device for compressing an associated gas separated in crude oil refining process to be reinjected into a reservoir, and a liquefied natural gas production offshore facility supplied with a feed gas including at least a part of the associated gas from the crude oil production offshore facility, and processing and liquefying the feed gas to generate a liquefied natural gas. The crude oil production offshore facility includes a feed gas supply unit for recovering a back-flow gas formed when an injection gas compressed by the gas reinjection device flows backward and generating the feed gas by using the back-flow gas.

An offshore LNG processing plant includes a first module including a personnel accommodation facility on a first vessel, a second module including a gas treatment facility on a second vessel, and a third module including a gas liquefaction facility on a third vessel. Each of the first, second, and third modules are assembled on the corresponding vessels, and then transported to an offshore location in a body of water, such as a river, a lake, or a sea. At the offshore location, each vessel deploys legs to the bed of the body of water to raise a hull of each vessel out of the water. The first module is then coupled to the second module, and the second module is coupled to the third module. A fourth module on a fourth vessel is coupled to the third module to provide LNG storage.

This invention provides a means of loading, processing and conditioning raw production gas, production of CGL, storage, transport, and delivery of pipeline quality natural gas or fractionated products to market. The CGL transport vessel utilizes a pipe based containment system to hold more densely packed constituents of natural gas held within a light hydrocarbon solvent than it is possible to attain for natural gas alone under such conditions. The containment system is supported by process systems for loading and transporting the natural gas as a liquid and unloading the CGL from the containment system and then offloading it in the gaseous state. The system can also be utilized for the selective storage and transport of NGLs to provide a total service package for the movement of natural gas and associated gas production. The mode of storage is suited for both marine and land transportation and configured in modular form to suit a particular application and/or scale of operation.

The present disclosure relates to a recycling system for recycling of composite materials such as wind turbine blades. The recycling system comprises a plurality of processing units that may be transported to a location of interest and assembled into the recycling system. Each processing unit configured to carry one or more recycling step(s).

The invention relates to a floating vessel (1) for energy harvesting, comprising:a hull (2), and a wave power plant (10). The wave power plant comprises:an inlet (11) arranged to receive waves of water, said inlet (11) leading to a transport channel (12) arranged with an angle to convey and lift water entering the inlet (11),5said transport channel (12) leading to an elevated basin (13) arranged to receive water, and said basin (13) having an outlet to a turbine (14T) below said basin (13), said turbine (14T) running an electrical generator (14G) for converting the potential energy of the water to electrical energy.

A floatable frame structure has concatenated frame modules, each formed of columns arranged substantially vertically. Neighboring columns are interconnected by upper and lower tie bars and form module sections. The connections between the tie bars and columns have rotary joints arranged at upper and lower nodes on the columns. At least one horizontal rotation joint is arranged for each column in the connection to an associated tie bar, and at least one spherical rotary joint or elastic rotary joint is arranged for each tie bar. Each module section is provided with elastic tensile elements secured to diagonally opposite upper and lower nodes, nodes lying diagonally opposite each other in the same horizontal plane and in the same frame module being connected by elastic tensile elements. Some columns form containers with submersible portions with positive buoyancy, and adjacent frame modules sharing at least one column.