Provided is a microtrencher having a utility avoidance system that detects objects buried under the roadway, identifies whether the buried object is a utility and determines whether the buried utility is in the path of the cutting wheel. If the buried utility is in the path of the cutting wheel, an alert is sent to the operator, the vehicle is stopped, and/or the cutting wheel is raised in relation to the roadway. Also provided is a method of using the microtrencher to cut a microtrench in a roadway and to avoid cutting a buried utility in the path of the cutting wheel.

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.

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.

A system for measuring the depth and location of a buried pipeline includes a probe having a GPS receiver, an elevation sensor, and a removable tablet computer for capturing data corresponding to the position and elevation of an underground pipeline and the corresponding soil surface covering the pipeline. Collected data is aggregated at a central computer which produces topographical maps of the pipeline's current relationship to the soil and calculates a desired soil covering. The calculated amount and placement of soil to achieve a desired end topography is used in abatement of any soil erosion or compaction. In alternative embodiments the required soil for abatement is transmitted to earth moving equipment.

A heavy equipment hazard warning apparatus for a piece of heavy equipment at a site and a system and method for use of the same are disclosed. In one embodiment of the heavy equipment hazard warning apparatus, the location of the heavy equipment is monitored by the heavy equipment warning apparatus and analyzed with reference to a hazard safety site plan of the site that identifies a hazard such as existing utilities, for example. An alert notification is initialized in response to the heavy equipment encroaching on a hazard geofence around the hazard. A shutdown notification is initialized in response to the heavy equipment being proximate to the hazard.

An implement for use with an excavator includes a lightweight housing, a first coupling feature, a ground penetrating radar antenna, a controller, a wireless communication circuit and a rotation unit. The lightweight housing has an upper surface, a lower surface and a cavity. The first coupling feature is located on the upper surface and cooperates with a second coupling feature on an excavator arm. The ground penetrating radar antenna is mounted near the lower surface. The controller is mounted within the cavity and provides outgoing signals to the radar antenna, receives incoming signals from the radar antenna and interprets the incoming signals so as to provide implement output information. The wireless communication circuit is mounted within the cavity and transmits the implement output information. The rotation unit is mounted within the cavity and rotates the housing vis--vis the excavator arm.

Images, which are captured by an image capture device on a ground disturbing work machine, and that are taken from different perspectives, and are received. A machine learned image identification model identifies items of interest in the images. A three-dimensional representation is generated based on the set of images. The three-dimensional representation identifies a depth at which the recognized items lie beneath the surface of the soil being excavated. A map request is received which identifies a location and depth for which image data is to be provided. A three-dimensional representation of the location and depth are provided in response to the request.

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.

A system and method for increasing friction between cables and surrounding soil is disclosed. In particular, a cable apparatus for use in a sub-surface protective network of intertwined cables is provided which comprises an elongate reinforced polymer cable body having a length. The cable apparatus also includes a plurality of elongate barbs provided along the length of the cable body. The barbs extend from the cable body to a respective free end in both a lengthwise direction and radially. Additionally, the barbs are spaced apart in one or more of the lengthwise direction along the length of the cable body and circumferentially about the cable body. Moreover, according to a further aspect, a plurality of such cables can be provided underground and intertwined to define a protective network cables for protecting buried assets.

A shovel (100) according to an embodiment of the present invention includes a lower travelling body (1), an upper pivot body (3) pivotably mounted to the lower travelling body (1), an excavation attachment (AT) provided to the upper pivot body (3), a plurality of actuators that operate the excavation attachment (AT), an operation device (26) provided to the upper pivot body (3), and a controller (30) configured to, in response to an operation of the operation device (26) in a first direction, operate the plurality of actuators to move a predetermined portion of the excavation attachment (AT) based on position information. The controller (30) operates the plurality of actuators in a first control mode and a second control mode based on the position information.