A shoring element has a shoring plate and a shaft received within a shaft receiver of the shoring plate. The shoring plate is rotatable and is permitted limited axial movement along the shaft. During installation, rotating the shaft in a first direction drives the shaft into the ground formation and causes the drive collar to contact a drive shoulder of the shoring plate such that the drive collar applies a driving force to the shoring plate. During removal, the shaft is rotated in a second direction to withdraw the shaft from the ground formation and the drive collar to move away from the drive shoulder. Applying an upward force to the lifting points causes the shoring plate to move axially relative to the shaft.

A shoring element has a shoring plate and a shaft received within a shaft receiver of the shoring plate. The shoring plate is rotatable and is permitted limited axial movement along the shaft. During installation, rotating the shaft in a first direction drives the shaft into the ground formation and causes the drive collar to contact a drive shoulder of the shoring plate such that the drive collar applies a driving force to the shoring plate. During removal, the shaft is rotated in a second direction to withdraw the shaft from the ground formation and the drive collar to move away from the drive shoulder. Applying an upward force to the lifting points causes the shoring plate to move axially relative to the shaft.

Disclosed is a base body of an electric transmission tower using a micropile. The base body of the electric transmission tower using the micropile includes an anchor member coupled to a main pole member of the electric transmission tower, a foundation member coupled to the anchor member and including a plurality of foundations, and the micropile configured to fix the foundation member to the ground and compress the foundation member.

The present disclosure provides an annular anchor recycling instrument and an annular anchor recycling method, relating to the technical field of ocean engineering. The annular anchor recycling instrument includes a recycling tube, a pump body assembly, a lifting portion and an installation portion. One end of the recycling tube is provided with a cover body, and the other end of the recycling tube is configured to be an open end for cooperating with the top of the annular anchor. The pump body assembly is arranged on the cover body, and used to boost pressure to the interior of the recycling tube. The lifting portion is arranged on the cover body, and used to connect with a hoist. The installation portion are arranged on the cover body, and used to connect with the anchor chain on the annular anchor.

The present disclosure provides an annular anchor recycling instrument and an annular anchor recycling method, relating to the technical field of ocean engineering. The annular anchor recycling instrument includes a recycling tube, a pump body assembly, a lifting portion and an installation portion. One end of the recycling tube is provided with a cover body, and the other end of the recycling tube is configured to be an open end for cooperating with the top of the annular anchor. The pump body assembly is arranged on the cover body, and used to boost pressure to the interior of the recycling tube. The lifting portion is arranged on the cover body, and used to connect with a hoist. The installation portion are arranged on the cover body, and used to connect with the anchor chain on the annular anchor.

The invention relates to a method of operating a mobile work machine with a ground pressure limitation and to a corresponding work machine. A maximum permitted ground pressure is compared with an actually present ground pressure.

The invention relates to a method of operating a mobile work machine with a ground pressure limitation and to a corresponding work machine. A maximum permitted ground pressure is compared with an actually present ground pressure.

An anchoring system installed on a bottom of a body of water. The anchoring system has a tube sheet with an access tube defining a flow channel therethrough. One or more water tubes pass through the tube sheet. Each of the water tubes defining a longitudinal channel through the tube sheet. Each longitudinal channel has an open end at the top side and a closed end below the bottom side. A plurality of flow channels pass through the tube sheet. A skirt extends from the bottom of the tube sheet and defines a volume within the skirt encompassing at least a portion of the water tubes and the flow channels. A shock absorber is coupled to the closed end of at least one of the plurality of water tubes. The anchoring system is installed using negative pressure and extracted using positive pressure.

An anchoring system installed on a bottom of a body of water. The anchoring system has a tube sheet with an access tube defining a flow channel therethrough. One or more water tubes pass through the tube sheet. Each of the water tubes defining a longitudinal channel through the tube sheet. Each longitudinal channel has an open end at the top side and a closed end below the bottom side. A plurality of flow channels pass through the tube sheet. A skirt extends from the bottom of the tube sheet and defines a volume within the skirt encompassing at least a portion of the water tubes and the flow channels. A shock absorber is coupled to the closed end of at least one of the plurality of water tubes. The anchoring system is installed using negative pressure and extracted using positive pressure.

Manoeuvring member (1) provided with a frame (10) comprising an axial-symmetrical tubular portion (100) internally delimited by an inner cylindrical mantle (102) extending in a given direction (D); the frame (10) being provided with a first end (12) and with a second end (14); a blocking device (30) being associated with the second end (14); the blocking device (30) comprising at least one pin (32) carried by the second end (14) in a radially movable manner between a back position (P1), where the pin (32) is arranged flush with the cylindrical mantle (100), and a forward position (P2), where the pin (32) projects inside the cylindrical mantel (102); the blocking device (30) being of the hydraulic type.