Disclosed are methods and apparatus for identifying non-metallic subterranean structures using amorphous metal markers associated with the structures. Some examples will include the amorphous metal in the form of one or more sections of an amorphous metal foil within a protective enclosure sufficient to physically isolate the amorphous metal foil from the surrounding Earth. The amorphous metal foil and enclosure may be in the form of a tape which either will be secured to, or placed proximate the subterranean structure, which may be, for example, a pipe or conduit, or other non-metallic structure.

A vibratory plow has a lift bracket. The lift bracket couples to an upper link by an upper spring having an upper energy absorptive member. The upper spring and upper energy absorptive member are configured to limit upper link movement relative to the lift bracket in a first direction. The lift bracket is coupled to the upper link by a lower spring having a lower energy absorptive member; the lower spring and lower energy absorptive member are configured to limit upper link movement relative to the lift bracket in a direction opposite the first direction. The upper link is coupled to a shaker box which is attached to a plow blade. The shaker box is configured to travel from a baseline position a first distance greater than two inches in the first direction before the upper spring compresses enough that the upper energy absorptive member dampens shaker box movement.

Disclosed are methods and apparatus for identifying non-metallic subterranean structures using amorphous metal markers associated with the structures. Some examples will include the amorphous metal in the form of one or more sections of an amorphous metal foil within a protective enclosure sufficient to physically isolate the amorphous metal foil from the surrounding Earth. The amorphous metal foil and enclosure may be in the form of a tape which either will be secured to, or placed proximate the subterranean structure, which may be, for example, a pipe or conduit, or other non-metallic structure.

Systems and methods for trenchless placement of an underground protective network of intertwined cables for protecting buried assets from accidental damage are disclosed. The system includes an apparatus for towing behind a vehicle and laying a plurality of continuous cables directly underground and interweaving the cables to form a cable network. The apparatus includes a plurality of soil rippers mounted at respective radial positions to a rotating carrier. The rotating carrier rotates about an axis that is at least partially normal to the ground surface. The rippers plow through the ground in the direction of vehicle travel and include a cable-feeding guide for directly and continuously feeding cable out underground during operation. In operation, the combined movement of the soil rippers from rotating the carrier and movement in the direction of travel serves to intertwine the cables deposited by respective rippers forming the protective network of intertwined cables.

Disclosed are methods and apparatus for identifying non-metallic subterranean structures using amorphous metal markers associated with the structures. Some examples will include the amorphous metal in the form of one or more sections of an amorphous metal foil within a protective enclosure sufficient to physically isolate the amorphous metal foil from the surrounding Earth. The amorphous metal foil and enclosure may be in the form of a tape which either will be secured to, or placed proximate the subterranean structure, which may be, for example, a pipe or conduit, or other non-metallic structure.

A method and apparatus for installing a monitoring cable or other utility near an existing pipeline. An electromagnetic signal may be induced on the pipeline, either directly, or by transmitting a signal from a vehicle carrying a sensor array. The sensors disposed on the vehicle communicate with a processor to determine a distance and orientation of the vehicle relative to the pipeline. The signal may be electromagnetic, acoustic, capacitive, or the like. A plow or other digging tool may be on the vehicle or a secondary vehicle. Such a digging tool opens a trench and installs the cable along a path disposed next to the pipeline within an acceptable distance range from the pipeline. The vehicle may be remotely or automatically operated.

Systems and methods for trenchless placement of an underground protective network of intertwined cables for protecting buried assets from accidental damage are disclosed. The system includes an apparatus for towing behind a vehicle and laying a plurality of continuous cables directly underground and interweaving the cables to form a cable network. The apparatus includes a plurality of soil rippers mounted at respective radial positions to a rotating carrier. The rotating carrier rotates about an axis that is at least partially normal to the ground surface. The rippers plow through the ground in the direction of vehicle travel and include a cable-feeding guide for directly and continuously feeding cable out underground during operation. In operation, the combined movement of the soil rippers from rotating the carrier and movement in the direction of travel serves to intertwine the cables deposited by respective rippers forming the protective network of intertwined cables.

Vehicles having a control console that may be moved between a plurality of locations relative to the body of the vehicle are disclosed. The control console may include a direction control device for controlling movement of the vehicle that is adaptive such that movement of the vehicle is based on both the direction at which the direction control device is actuated and the sensed position of the control console.

Systems and methods for trenchless placement of an underground protective network of intertwined cables for protecting buried assets from accidental damage are disclosed. The system includes an apparatus for towing behind a vehicle and laying a plurality of continuous cables directly underground and interweaving the cables to form a cable network. The apparatus includes a plurality of soil rippers mounted at respective radial positions to a rotating carrier. The rotating carrier rotates about an axis that is at least partially normal to the ground surface. The rippers plow through the ground in the direction of vehicle travel and include a cable-feeding guide for directly and continuously feeding cable out underground during operation. In operation, the combined movement of the soil rippers from rotating the carrier and movement in the direction of travel serves to intertwine the cables deposited by respective rippers forming the protective network of intertwined cables.

Vehicles having a control console that may be moved between a plurality of locations relative to the body of the vehicle are disclosed. The control console may include a direction control device for controlling movement of the vehicle that is adaptive such that movement of the vehicle is based on both the direction at which the direction control device is actuated and the sensed position of the control console.