An ecological city system is provided including a core structure and a set of circularly arranged structures having various functions surrounding the core. A plurality of radially arranged transportation structures provide transportation between the circularly arranged structures and the core structure. The ecological city system sustains inhabitant life via a closed loop system for maximizing ecological sustainability, ecological harmony, inhabitant safety, and economic performance and efficiency.

An ecological city system is provided including a core structure and a set of circularly arranged structures having various functions surrounding the core. A plurality of radially arranged transportation structures provide transportation between the circularly arranged structures and the core structure. The ecological city system sustains inhabitant life via a closed loop system for maximizing ecological sustainability, ecological harmony, inhabitant safety, and economic performance and efficiency.

A modular structure, configured to be connectable with a plurality of modular structures to form an enclosed transportation path, each modular structure including a bottom element structured and arranged to provide a track support surface and a plurality of upper element attachment structures, and an upper element configured to attach to the bottom element at the plurality of upper element attachment structures, wherein the upper element is structured to sealingly engage with the lower element.

A modular structure, configured to be connectable with a plurality of modular structures to form an enclosed transportation path, each modular structure including a bottom element structured and arranged to provide a track support surface and a plurality of upper element attachment structures, and an upper element configured to attach to the bottom element at the plurality of upper element attachment structures, wherein the upper element is structured to sealingly engage with the lower element.

The invention relates to a device (1) for securing functional objects between the rails (2, 3) of a railway track comprising: a base unit (4) sized so as to be disposed between the rails (2, 3), a first securing element (5, 7) arranged so as to secure one part of the base unit (4) to one (2) of the rails, a second securing element (6, 8) arranged so as to secure another part of the base unit to the other (3) of the rails, at least one attachment element (9, 10) arranged so as to secure the base unit (4) to at least one functional object (11). The invention also relates to a method and a machine for placing and securing functional objects (11) between the rails (2, 3) of a railway track. The invention also relates to a reverse method and the machine can also be used for removing the functional objects (11).

A system for and method of stabilizing rail track structures using a load transfer apparatus is disclosed. The load transfer apparatus includes a vertical load transfer element and a top load transfer element, wherein the top load transfer element is used to transfer applied locomotive and rail car loads to the vertical load transfer element. In one embodiment, the top load transfer element includes helical flights. In another embodiment, the top load transfer element includes a flared top. In yet another embodiment, the top load transfer element includes a load transfer cap. In a further embodiment, the top load transfer element includes two or more support legs each with a top support attached thereto. The railroad stabilization system can comprise any one type or any combinations of types of the aforementioned load transfer apparatuses.

A precast H block (3) interlock each other to form sloping wall and similarly precast Y block (10) interlock each other to form straight wall, both block having a pin hole (4) through side walls. A wire rope (5) passing through said pin hole to make a wall strengthened by nailing horizontally (14) into the earth (8) adjacent to the block and vertically nailing (9) at top and bottom level. As well as wire rope (5) passing through said pin hole (4) of uppermost blocks, from underneath the road, to make a wall/barrier strengthened by nailing vertically (9) into the earth across the road (2).

The present invention relates to a process and to a system for laying tracks for ballastless railway and tramway lines, both in tunnel and in surface.

A cut and cover method of constructing grade separation structures includes partially burying precast substructure elements with associated trench boxes under live traffic. Once the precast substructure elements are buried, the substructure is completed and the bridge span is installed. Other methods include installing precast superstructure elements with a formwork system and forming a bridge substructure and excavating underneath the superstructure once the superstructure is formed.

A cut and cover method of constructing grade separation structures includes partially burying precast substructure elements with associated trench boxes under live traffic. Once the precast substructure elements are buried, the substructure is completed and the bridge span is installed. Other methods include installing precast superstructure elements with a formwork system and forming a bridge substructure and excavating underneath the superstructure once the superstructure is formed.