A jig for a fusion splicer mountable on a heater of the fusion splicer includes: a plate part configured to face a heating part of the heater; a first retainer, configured to face a first clamp of the fusion splicer that is disposed outside of the heating part along a longitudinal direction of an object to be heated, and further configured to retain a first member extending from a first end of the object along the longitudinal direction; and a second retainer, configured to face a second clamp disposed on a side of the heating part opposite to the first clamp along the longitudinal direction, and further configured to retain a second member extending from a second end of the object along the longitudinal direction.

An example single-station splicing unit is provided that includes a housing, an alignment element, a first electrode, and a second electrode. The housing includes an interior space and at least one cover configured to be interlocked with the housing to enclose the interior space. The alignment element is disposed within the interior space of the housing. The first electrode is disposed on one side of the housing, and the second electrode is disposed in the housing on an opposing side from the first electrode and in a facing relationship with the first electrode. The housing is configured to receive fibers in an opposing and abutting relationship to splice the fibers, and the housing remains secured to the fibers after splicing.

An optical receptacle includes: a first optical fiber; a second optical fiber connected to the first optical fiber by fusion splice; a ferrule including a fiber hole that holds an end of the first optical fiber; and a housing portion that houses therein: the ferrule, the first optical fiber, and a first portion of the second optical fiber. A fusion splice portion between the first optical fiber and the second optical fiber is disposed outside of the ferrule and within the housing portion.

Provided is an optical fiber ribbon capable of achieving higher density and reduction in diameter and accurately placing optical fibers in V-shape grooves in a fusion machine without failure. The optical fiber ribbon 1 includes three or more of optical fibers 2 arranged in parallel and connecting portions 3 connecting adjacent two optical fibers 2 together, the connecting portions 3 being intermittently provided in each of a ribbon longitudinal direction and a ribbon width direction. The connecting portions 3 are each formed in such a manner as to fill resin into a gap S formed between adjacent two optical fibers 2, and both surfaces of the respective connecting portions 3 are each formed into a recess having a concave shape curved toward a center of the gap S to separate from lines 4,5 each connecting contact points of the optical fibers 2 when being placed on a horizontal surface.

Provided is an optical fiber ribbon capable of achieving higher density and reduction in diameter and accurately placing optical fibers in V-shape grooves in a fusion machine without failure. The optical fiber ribbon 1 includes three or more of optical fibers 2 arranged in parallel and connecting portions 3 connecting adjacent two optical fibers 2 together, the connecting portions 3 being intermittently provided in each of a ribbon longitudinal direction and a ribbon width direction. The connecting portions 3 are each formed in such a manner as to fill resin into a gap S formed between adjacent two optical fibers 2, and both surfaces of the respective connecting portions 3 are each formed into a recess having a concave shape curved toward a center of the gap S to separate from lines 4,5 each connecting contact points of the optical fibers 2 when being placed on a horizontal surface.

A fusion splicing device includes a fusion splicing unit, a fusion splicing control unit, an imaging unit, and a notification unit. The fusion splicing unit fusion-splices optical fibers by discharge between a pair of electrode rods. The fusion splicing control unit controls an operation of the fusion splicing unit and has an operation mode for performing a discharge test. The imaging unit generates image data of a fusion spliced portion of the optical fibers. The notification unit notifies various kinds of information. The discharge test is to fusion-splice the optical fibers, to check a fusion-spliced state of the optical fibers on the basis of the image data, and to adjust a fusion splicing condition to be close to an optimum condition. When a predetermined start condition is satisfied, the fusion splicing control unit causes the notification unit to notify information for requesting execution of the discharge test.

A method of forming a splice to join two optical fibres comprises: providing two optical fibres, at least one of which is a hollow core optical fibre; aligning an end of one of the optical fibres with an end of the other optical fibre such that longitudinal axes of the two optical fibres are substantially along a same line and the ends of the optical fibres are spaced apart; performing a prefusion stage (S1) comprising: applying an electric arc proximate the ends of the optical fibres in order to soften the material of the ends; moving the ends of the optical fibres together to make contact and then exceed the contact by an overlap distance to form a fused portion in which the ends are fused together; and performing at least one pushing stage (S2), each pushing stage comprising: implementing a cooling period during which no electrical arc is applied; at the end of the cooling period, applying an electrical arc to the fused portion to soften the material of the fused ends; and pushing the fused ends of the optical fibres further together.

The present invention relates to a fiber exit element (1), comprising: a plurality of glass fibers (10) each having at least one core (10a) which is designed to guide a signal light ray (A); and at least one optical element (14), preferably an optical window (14), an optical lens (14), an optical beam splitter (14) or an optical prism (14), which is connected to each open end (11) of the cores (10a) of the glass fibers (10) and is designed to receive the signal light ray (A) from the open ends (11) of the cores (10a) of the glass fibers (10) and to output said signal light ray to the outside via at least one exit face (14b) as exit rays (A′). The fiber exit element (1) is characterized in that the open ends (11) of the cores (10a) of the glass fibers (10), and preferably also the open ends (11) of claddings (10b) of the glass fibers (10) substantially enclosing the cores (10a), are each arranged within the material of the optical element (14) with a depth of penetration (W), preferably with respect to an incident face (14a) of the optical element (14), at least the material of the open ends (11) of the cores (10a) of the glass fibers (10), preferably also the material of the open ends (11) of the claddings (10b) of the glass fibers (10), being fused to the material of the optical element (14).

The present description relates to a modular, reconfigurable splice tray system that comprises a splice tray having a base extending longitudinally from a first end to a second end, a pair of side walls extending longitudinally between the first and second ends of the base, a plurality of cable entrances formed at the first and second end of the base and a receiving portion configured to receive a modular component disposed between the cable entrances at the first end and at the second end.

A reinforcement device for an optical fiber fusion-spliced portion, which reinforces a fusion-spliced portion of optical fibers by heating and shrinking a reinforcement sleeve covering the fusion spliced portion, includes a heater configured to heat the reinforcement sleeve. The heater includes a sleeve housing portion capable of housing the reinforcement sleeve. The sleeve housing portion includes a first wall portion extending in a longitudinal direction of the sleeve housing portion and a second wall portion facing the first wall portion. The first wall portion and the second wall portion are configured such that a distance therebetween increases from a bottom portion side of the sleeve housing portion toward a top portion side of the sleeve housing portion in a cross-section orthogonal to the longitudinal direction. At least one bent portion is formed to at least one of the first wall portion and the second wall portion in the cross-section.