The present disclosure relates to a grouting cabin structure of a grouted connection for use in a foundation of an offshore wind turbine generator. The structure is suitable for use in offshore wind power industry.
At present, structures for foundations of offshore wind turbine generators usually employ grouted connections. For example, for a mono-pile foundation, a tower is connected with a pile via a grouted connection; for a tripod foundation and jacket foundation, a jacket is connected with piles via a grouted connection between pile sleeves and piles.
In practical implementation, performance of grouted connections can be improved by enhancing the strength of the grouting material and improving grouting techniques, and structural designs of grouted connections also play an important role. The roughness of pipe walls impacts the friction between the pipe and the grout; shear keys may enhance mechanical bond forces. However, all these stress modes are passive. Therefore, it is desired to enhance the bearing capacity of grouted connections by means of active holding actions of pre-stresses.
To solve one or more of the above mentioned problems, the present disclosure provides a grouting cabin structure of a grouted connection for use in a foundation of an offshore wind turbine generator (WTG). By arranging an enclosed cabin at a grouted connection section and by means of grouting and pressurized grouting, an active holding force within the grouted connection section can be generated and, as a result, the bearing capacity of the grouted connection section can be enhanced.
The present disclosure provides a grouting cabin structure of a grouted connection for use in a foundation of an offshore wind turbine generator (WTG), the structure comprising a pile (2), a sleeve (1) which is coaxial with said pile (2) and installed outside said pile (2), a first grouting exhaust (5-1) and a first connection port (7-1) for a grouting pipe provided at an upper part and a lower part of said sleeve (1) respectively. An enclosed cabin of a barrel form is provided in a gap between said pile (2) and said sleeve (1) and is concentric and coaxial with them. Said enclosed cabin is formed by an internal wall (3) of said cabin and said sleeve (1). A second connection port (7-2) for a grouting pipe and a second grouting exhaust port (5-2) are provided at a lower part and an upper part of the enclosed cabin, hence close to a side of said sleeve (1). A gap between the internal wall (3) of the said cabin and an external wall of said pile (2) forms a first grouting space (6) and a gap between said internal wall (3) of said cabin and said sleeve (1) forms a second grouting space (4).
The grouting cabin structure may comprise a plurality of said enclosed cabins, which may be arranged in intervals.
In the grouting cabin structure, a thickness of an internal wall (3) of said cabin may be 2 mm˜T/5, wherein T refers to a thickness of a wall of said sleeve (1).
In the grouting cabin structure, a first set of one or more shear keys (8) may be arranged on an external wall of said pile (2), and a second set of one or more shear keys (3-1) may be arranged on an internal wall (3) of said cabin at a side facing said pile (2). Said first set of shear keys (8) and said second set of shear keys (3-1) may be arranged in a staggered way.
The grouting cabin structure provided by the present disclosure feature at least the following advantages: By arranging an enclosed cabin in a grouted connection section and by means of grouting and pressurized grouting in said cabin, active holding forces (pre-stresses, including pre-stress due to expansion of grouting materials) can be generated within the grouted connection section between the internal wall of the cabin and the external wall of the pile; as a result, the performance of the grouted connection section can be enhanced.
As shown in
Where necessary, partitioned design may be employed for the enclosed cabin based on optimization calculations. That is to say, a plurality of said enclosed cabins may be provided in intervals, as shown in
It is advantageous to add expansion agent to grouting materials so as to enhance the effect of pre-stresses due to expansion.
In this embodiment, said sleeve (1) may be connected to a tower (11) of the wind turbine generator via a flange (10).
In this embodiment, a connection between said enclosed cabin and said sleeve (1) may be prefabricated in a factory. After said pile (2) is inserted into said sleeve (1), they are concentric and coaxial with each other.
During construction, the following process may be employed: Firstly, grouting said first grouting space (6) between said internal wall (3) of said cabin and an external wall of said pile (2); then grouting said second grouting space (4) in said cabin; closing the grouting exhaust port when mortar spills out; continuing with grouting to enhance the pressure in said enclosed cabin (by increasing pressure) until the pressure in said enclosed cabin reaches a predefined value. (The expansion effects of grouting materials comprising expansion agents on pre-stresses and the decay of pre-stresses after a still period should be considered. The actual value of the pressure should be determined based on test data or test results.)
When the pressure in said enclosed cabin reaches the predefined value, stop grouting and close said connection port of the grouting pipe. At this time, said enclosed cabin provides an active holding action (viz. pre-stress) to said first grouting space (6) and said pile (2).
Referring to
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