An apparatus for feeding a tubular object inside a drill hole, a rock drilling rig and a method of supporting mouth openings of drill holes is provided. The apparatus includes a support device for supporting an elongated tube element blank having the potential for several successive tube inserts. A front end of the tube element blank is moved longitudinally inside a drill hole by means of a feeding device. Thereby, the drill hole is provided with a protective section extending a limited longitudinal dimension towards a bottom of the drill hole. The apparatus further includes a separation device for detaching the mentioned tube inserts one by one from the tube element blank.

A drilling and bolting device for driving a drill element into a rock surface includes a frame, a drive unit supported for movement relative to the frame, and an actuator for moving the drive unit relative to the frame. The drive unit includes a motor and a chuck for engaging the drill element. The chuck is driven by the motor. In some aspects, the actuator includes a magnet exerting a magnetic force on the block to provide magnetic coupling between the actuator and a block supporting the motor. In some aspects, the actuator is positioned at least partially within an elongated member of the frame. In some aspects, the drive unit includes a switched reluctance motor including a stator and a rotor supported for rotation relative to the stator, and the rotor is directly coupled to the chuck.

A handling system for handling expendables for a drill rig arranged for automated handling of the expendables is provided. The handling system includes a pickup mechanism configured to move an expendable back and forth between a magazine of the drill rig for expendables and a loading position within the drill rig, a first outer guide device configured to receive and guide the expendable, optionally grip and hold the trailing portion of the expendable when the expendable is in an outer extreme position, and a second outer guide device provided adjacent the first outer guide device between the first outer guide device and an inner guide device.

A robotic apparatus (1) for performing drill floor operations comprises a support arrangement (2) and at least one manipulator arm (6). The at least one manipulator arm (6) is configured to carry an end effector (11) configured to manipulate one or more of tubing, tools and/or equipment on a drill floor (d) or pipe deck of an oil and gas rig in order to perform a given drill floor operation.

A pipe storage system can include a plurality of pipe storage bays established between adjacent pipe storage arms, a plurality of protrusions extending from the pipe storage arms into each pipe storage bay, the plurality of protrusions establishing a plurality of channels, wherein each channel is established between a pair of adjacent protrusions, and a plurality of latches, wherein the latches are movable from between a retracted position in which the latches are retracted to establish series of first pipe storage openings between opposing channels and an extended position in which the latches extend into the pipe storage bay to establish a series of second pipe storage openings between opposing protrusions.

An apparatus serves to grip a cable for delivery into a borehole in a surface of a mine passage in connection with an actuator, such as a drill mast having a carriage capable of being advanced and retracted along the drill mast. A pusher is formed from a pair of jaws for engaging the cable. The jaws may be biased toward a first position for engaging the cable during an advance of the carriage, and automatically movable to a second position for releasing from engagement with the cable during a retraction of the carriage. The pusher may be pivotally mounted to a carriage capable of being advanced and retracted along a drill mast, which movement may cause the jaws to self-actuate for engaging and advancing the cable during an upstroke and release therefrom during a downstroke. Related methods are also disclosed.

An apparatus serves to grip a cable for delivery into a borehole in a surface of a mine passage in connection with an actuator, such as a drill mast having a carriage capable of being advanced and retracted along the drill mast. A pusher is formed from a pair of jaws for engaging the cable. The jaws may be biased toward a first position for engaging the cable during an advance of the carriage, and automatically movable to a second position for releasing from engagement with the cable during a retraction of the carriage. The pusher may be pivotally mounted to a carriage capable of being advanced and retracted along a drill mast, which movement may cause the jaws to self-actuate for engaging and advancing the cable during an upstroke and release therefrom during a downstroke. Related methods are also disclosed.

Aspects of the present disclosure relate to a stand break detection system. In some embodiments, the stand break detection system includes a sensor and a data processing system. The sensor may measure a movement of drill pipe as it is tripped out of a wellbore. The processor may execute instructions stored in a memory to receive measured movement data from the sensor and identify a stand break associated with one or more drill pipes using the measured movement data.

Provided is an underground development drill return system comprising a front limit sensor and front sensor actuator, each configured for operative mounting at opposite ends of a forward drill feeder length of a drilling arm of the drill. System also includes a rear limit sensor and rear sensor actuator, each configured for operative mounting at opposite ends of a return drill feeder length of the drilling arm. Each limit sensor comprises a proximity sensor with a wireless transmitter for transmitting a limit signal upon activation of the sensor, and each sensor actuator comprises an actuator for actuating the respective sensor when brought into proximity thereof.

A system includes an upper sheave configured to orient a cable towards a well, a lower sheave, having a center, configured to orient the cable towards the upper sheave, and a sheave stand. The sheave stand includes a shaft, running through the center of the lower sheave, configured to enable rotation of the lower sheave about a central axis, a sheave holder, fixed to the shaft, configured to hold the lower sheave in a vertical position, a tool leg, fixed to the shaft, configured to elevate the shaft to a height above a surface, and a floor stand, fixed to the tool leg, configured to anchor the sheave stand to the surface. The sheave stand stabilizes the cable by maintaining the lower sheave in a fixed rotational position.