A guide tool device for an optical fiber or cord includes a tool base that mounts on an adhesive syringe. A cord guide head has a flat leading edge, a key removably insertable into a keyway in the tool base, a guide channel for guiding a fiber toward the leading edge, and a tube for receiving an adhesive. An opening in the guide channel communicates adhesive from the tube into the channel, for applying the adhesive along a fiber while it is guided toward the leading edge on the guide head. A fitting is arranged to connect in sealing relationship with a distal end of the syringe, and a flexible tubing is connected between the fitting and the other end of the tube on the cord guide head. When urged toward the distal end of the syringe, the adhesive is communicated into the guide channel in the cord guide head.

A pushing tool for propelling cable into a duct. The pushing tool includes a drive wheel that is coupled with a base and a rotatable handle. A first cable guide and a second cable guide are configured to hold the cable. A duct guide is configured to hold the duct. Furthermore, a tension wheel is configured to interact with the drive wheel such that an orifice is formed between the tension wheel and the drive wheel, the orifice being configured to receive the cable. Upon rotation of the rotatable handle, the drive wheel interacts with the tension wheel to propel the cable into the duct.

A pushing tool for propelling cable into a duct. The pushing tool includes a drive wheel that is coupled with a base and a rotatable handle. A first cable guide and a second cable guide are configured to hold the cable. A duct guide is configured to hold the duct. Furthermore, a tension wheel is configured to interact with the drive wheel such that an orifice is formed between the tension wheel and the drive wheel, the orifice being configured to receive the cable. Upon rotation of the rotatable handle, the drive wheel interacts with the tension wheel to propel the cable into the duct.

A female connector is connected to a male connector having a cylindrical hood portion open in the longitudinal direction and housing a plurality of terminals. The male connector has a holding portion holding a plurality of terminals arranged inside the hood portion when the female connector is connected to the male connector, a seal interposed between the outer surface of the holding portion and the inner surface of the hood portion, and a slider arranged along the outer surface of the hood portion. The slider is able to slide in the transverse direction and the sliding action causes the hood portion to be engaged so that force is applied to the hood portion in the direction in which the male connector connects to the female connector. A pressing portion is formed on the slider to press the hood portion into the holding portion.

A method, includes: detecting one or more properties of a waveguide having a downhole end and an uphole end; and responsive to the detected one or more properties, positioning into a passage of a wellbore the waveguide to minimize tension thereof.

A method, includes: detecting one or more properties of a waveguide having a downhole end and an uphole end; and responsive to the detected one or more properties, positioning into a passage of a wellbore the waveguide to minimize tension thereof.

An optical module is disclosed. The disclosed optical module may include a retractable structure having a housing and an upper cover. A clip component for connecting to a chassis is arranged within the housing. A release component for controlling the clip component is arranged on the upper cover. More space within the housing can be available for internal components of the optical module.

The specification relates to a fiber optic cable assembly. The fiber optic cable assembly includes: an outer sheath; fiberglass reinforced panels; a pull material; an inner jacket; a strength material; non-interlocking armor; and a tight buffer of optical fibers.

A fiber optic cable assembly comprises: a cable jacket; distinct groups of optical fibers carried within the cable jacket and extending beyond a first end of the cable jacket; a furcation body positioned on the first end of the cable jacket such that the distinct groups of optical fibers extend beyond the furcation body; and a pulling grip assembly having a proximal end selectively secured to the furcation body, a distal end opposite the proximal end, and an interior between the proximal end and the distal end that contains fiber end sections. The interior of the pulling grip assembly is sealed off from an exterior of the cable assembly to provide sealed protection for the fiber end sections over an ambient temperate range of at least between 20 to 50 C. while applying a tensile load of at least 300 lbs to the distal end of the pulling grip assembly.

The present disclosure relates to an apparatus (1) for installing a cable (2) in a duct (3). The apparatus comprises a blowing chamber (4) comprising a cable inlet and a cable outlet and a fluid inlet for receiving a supply of pressurized fluid, wherein the cable outlet is configured to be connected to the duct (3). The apparatus moreover comprises a pushing drive unit (50). Additionally, the apparatus comprises a first drive device (10) comprising a first conveyer pant (16a) and a second drive device (20) comprising a second conveyer pant (16b), wherein said conveyer pants (16a, 16b) are arranged at opposing sides of a cable guidance space (13) and wherein one or both conveyer pans (16a, 16b) are configured to induce a driving force (F1) onto apart of the cable arranged in the cable guidance space (13). One or both of the first and second conveyer pan (16a, 16b) is configured to be moved towards and away from the cable guidance space (13), and one or both of the first and second drive device (10, 20) comprises a base pan (a, 20a) at which the conveyer part (16a, 16b) is mounted. One or both of the first and second drive device (10, 20) comprises a coupling arrangement part (14a) configured to engage with a drive arrangement part (15) of the apparatus (1), wherein the drive arrangement part (15) is configured to be driven by the pushing drive unit (50). The base part (10a, 20a) is disconnectably connected to a socket part (30) of the apparatus (1) and is maintained in a locked position by means of a locking system (31a, 31b, 32a, 32b, 33a, 33b, 34a, 34b, 36, 17). The coupling arrangement part (14a) engages with the drive arrangement part (15) of the apparatus (1) when the base part (10a, 20a) is connected to the socket part (30) in the locked position. The disclosure moreover relates to a drive device, a set of drive devices and a method.