Patent Description:
Patent Document <NUM> discloses a fusion splicer which heats optical fibers for fusion splicing. The fusion splicer includes a coated part clamp (upper clamp member) that presses an optical fiber, and a movable stage positioned below the coated part clamp and configured to support the optical fiber. The movable stage can move forward and backward due to a power source. The power source of the movable stage is connected also to the coated part clamp by a gear train, and when the movable stage moves backward, an operation of opening the coated part clamp using power of the power source is performed.

Publication <CIT> discloses an optical fiber fusion splicer that heats and fusion-splices optical fibers to each other. The optical fiber fusion splicer includes a coating clamp installation base, a coating clamp that is attached to the coating clamp installation base and has a coating clamp lid that is openable and closable, and a first power source for advancing the coating clamp installation base and opening the coating clamp lid. An operation of opening the coating clamp lid is performed using the first power source after the fusion splicing is completed. The optical fiber fusion splicer further comprises a drive mechanism that advances the coating clamp installation base with the power of the first power source, and after the fusion splicing is completed, the drive mechanism is separated from the coating clamp installation base, and the operation of opening the coating clamp lid is performed with the power of the first power source transmitted via the drive mechanism after the separation from the coating clamp installation base.

Since a coated part clamp has a role of fixing an optical fiber at the time of fusion splicing, generally, a force (closing force) for maintaining the coated part clamp in a closed state is set strong. In the configuration of Patent Document <NUM>, in order to overcome the closing force and open the coated part clamp, it is required to increase a speed reduction ratio of the gear train between the power source and the coated part clamp. When the speed reduction ratio is increased, an operation time at the time of opening the coated part clamp becomes longer. Also, when a high-output power source is used, a speed reduction ratio and an operation time can be reduced, but this leads to an increase in size of the device.

The invention has been made in consideration of such circumstances, and an objective of the invention is to provide a fusion splicer in which an operation time at the time of opening a coated part clamp can be reduced while using a low-output power source.

In order to solve the above-described problems, a fusion splicer according to independent claim <NUM> is provided. Further embodiments are provided by the dependent claims. The fusion splicer according to the invention includes a heater which heats a glass part of an optical fiber, a lower clamp on which a coated part of the optical fiber is placed, a coated part clamp which sandwiches the optical fiber between the coated part clamp and the lower clamp, a windproof cover which covers the heater and the coated part clamp, and a retreat mechanism which causes the coated part clamp to retreat from the lower clamp, an opening/closing mechanism which drives the windproof cover, and a pair of glass clamps which are attached to an inner surface of the windproof cover. The retreat mechanism includes a power source, a rotating member which is rotatable around a rotation center, an elastic member that elastically deforms by power received from the power source and thereby stores elastic energy, a transmission part which pushes the coated part clamp upward due to an elastic force received from the elastic member, and a restricting part which restricts rotation of the rotating member while the elastic member stores the elastic energy in a state in which the windproof cover is closed, and the restricting part releases the elastic energy stored in the elastic member and thereby releases restriction on rotation of the rotating member in conjunction with an opening operation of the windproof cover.

According to the above-described aspect, the elastic member can be elastically deformed by driving the power source after the optical fiber is set and the windproof cover and the coated part clamp are closed. Then, since restriction on displacement of the transmission part is released in conjunction with an opening operation of the windproof cover after the fusion splicing is completed, the transmission part can be displaced and the coated part clamp can be pushed upward by the elastic force received from the elastic member. As described above, when power obtained from the power source is stored in the elastic member using a time while the fusion splicing or the like is performed and then an elastic energy is released in a short period of time, the coated part clamp can be opened by overcoming a closing force of the coated part clamp while using a low-output power source.

Here, the transmission part may include a pin which is positioned between the coated part clamp and the rotating member and is slidably movable in a vertical direction, and the pin may slide upward and push the coated part clamp upward when the rotating member receives the elastic force and rotates.

Also, the transmission part may include a rotating member which is rotatable around a rotation center, and the rotating member may push the coated part clamp upward when the rotating member receives the elastic force and rotates.

Also, in the fusion splicer according to the above-described aspect, the restricting part may be fixed to the windproof cover.

Further, the windproof cover may be constituted by a first segmented member driven by the opening/closing mechanism, and a second segmented member driven by a second opening/closing mechanism, and the restricting part may be fixed to the second segmented member.

Also, the windproof cover may be constituted by a first segmented member driven by the opening/closing mechanism, and a second segmented member driven by the power source, power of the power source may be transmitted to the second segmented member via the elastic member, and the restricting part may be fixed to the first segmented member and may release restriction on rotation of the rotating member in conjunction with an opening operation of the first segmented member.

According to the fusion splicer according to the above-described aspects of the invention, an operation time at the time of opening the coated part clamp can be reduced while using a low-output power source.

Hereinafter, a fusion splicer of a first embodiment will be described with reference to the drawings.

As shown in <FIG>, and <FIG>, a fusion splicer <NUM> is configured to fusion-splice a pair of optical fibers F1 and F2. Each of the optical fibers F1 and F2 includes a glass part G and a coated part C that covers the glass part G. The coated part C may be formed of a single layer or may be formed of a plurality of layers. The coated part C of the present embodiment includes a first coating layer C1 and a second coating layer C2 that covers the first coating layer C1 from an outward side. The first coating layer C1 and the second coating layer C2 are formed of a resin. Further, the coated part C may include three or more coating layers.

The fusion splicer <NUM> may be configured to collectively fusion-splice a first optical fiber unit including the optical fiber F1 and a second optical fiber unit including the optical fiber F2. That is, the fusion splicer <NUM> may fusion-splice single-core optical fibers F1 and F2 to each other or may collectively fusion-splice multicore optical fiber units to each other. That is, "fusion-splicing a pair of optical fibers" includes fusion-splicing multicore optical fiber units to each other.

The fusion splicer <NUM> includes a device main body <NUM> having a box shape in an external appearance. A windproof cover <NUM> is provided in an upper portion of the device main body <NUM>. The windproof cover <NUM> is rotatable around a rotation center 3a.

As shown in <FIG>, when the windproof cover <NUM> rotates around the rotation center 3a, a splicing structure <NUM> that fusion-splices the optical fibers F1 and F2 is exposed. The splicing structure <NUM> includes a heater 2a that heats the optical fibers F1 and F2.

Hereinafter, the splicing structure <NUM> of the present embodiment will be described with reference to <FIG>. In <FIG> and subsequent figures, each member is shown in a simplified manner for easy understanding of the structure.

As shown in <FIG>, the splicing structure <NUM> includes a pair of movable stages <NUM>, a pair of lower clamps <NUM>, a pair of glass holders <NUM>, a pair of glass clamps <NUM>, a pair of coated part clamps <NUM>, and a pair of electrode rods <NUM>. A direction in which the pair of movable stages <NUM> face each other and a direction in which the pair of electrode rods <NUM> face each other are perpendicular to each other.

In the present embodiment, a direction in which the pair of movable stages <NUM> face each other is referred to as a left-right direction X and is represented by an X axis. Also, a direction in which the pair of electrode rods <NUM> face each other is referred to as a front-rear direction Y and is represented by a Y axis. A vertical direction Z perpendicular to both the left-right direction X and the front-rear direction Y is represented by a Z axis.

The left-right direction X is also a direction in which the pair of optical fibers F1 and F2 extend. In the left-right direction X, a side closer to the pair of electrode rods <NUM> is referred to as an inward side, and a side away from the pair of electrode rods <NUM> is referred to as an outward side.

The splicing structure <NUM> has substantially a symmetrical structure in the left-right direction X with the pair of electrode rods <NUM> as a center.

Although not shown, the pair of electrode rods <NUM> are disposed at a distance in the front-rear direction Y. Each of the electrode rods <NUM> has a tapered shape in which an outer diameter decreases toward an inward side (a side approaching the optical fibers F1 and F2) in the front-rear direction Y. When abutting surfaces of the optical fibers F1 and F2 are disposed between the electrode rods <NUM> and electrical discharge is performed toward the abutting surfaces, distal ends of the optical fibers F1 and F2 can be heated and fusion-spliced. That is, the heater 2a of the present embodiment is constituted by the pair of electrode rods <NUM>. Further, a heater or the like may be used instead of the electrode rods <NUM> as the heater 2a.

The pair of movable stages <NUM> are disposed at a distance in the left-right direction X and are attached to the device main body <NUM>. Each of the pair of movable stages <NUM> is movable in the left-right direction X with respect to the device main body <NUM>. As shown in <FIG>, the pair of movable stages <NUM> are disposed to sandwich the electrode rods <NUM> therebetween when viewed from the front-rear direction Y. That is, the movable stages <NUM> can move forward and backward with respect to the electrode rods <NUM>. A power source (not shown, motor or the like) that drives the movable stages <NUM> is provided in the device main body <NUM>.

The pair of lower clamps <NUM> are formed in a plate shape and are respectively positioned on an upper side of the movable stages <NUM>. The lower clamps <NUM> are attachable to and detachable from the movable stages <NUM>. The pair of coated part clamps <NUM> are positioned above the lower clamps <NUM>. The lower clamp <NUM> and the coated part clamp <NUM> are fixed to the movable stage <NUM>. Therefore, when the movable stage <NUM> moves in the left-right direction X, the lower clamp <NUM> and the coated part clamp <NUM> also move in the left-right direction X.

The glass clamp <NUM> is positioned above the glass holder <NUM>. The glass clamp <NUM> is configured to open and close an upper surface of the glass holder <NUM> in conjunction with an opening and closing operation of the windproof cover <NUM>. In the present embodiment, the glass clamp <NUM> is attached to an inner surface of the windproof cover <NUM>. Also, a spring that applies a force to the glass clamp <NUM> downward is provided inside each of the pair of glass clamps <NUM>. With this configuration, when the windproof cover <NUM> is closed, the glass clamp <NUM> presses the glass part G of the optical fiber F1 or F2 due to the force applied thereto by the spring. Also, since the glass holder <NUM> is positioned below the glass clamp <NUM>, the glass part G of the optical fiber F1 or F2 is sandwiched between the glass clamp <NUM> and the glass holder <NUM> by the biasing force generated by the spring. On the other hand, when the windproof cover <NUM> is opened, the glass clamp <NUM> is also separated upward from the glass part G. As described above, the glass clamp <NUM> can switch between a state in which the glass part G is held and a state in which the glass part G is not held in conjunction with the opening and closing operation of the windproof cover <NUM>.

As shown in <FIG>, the glass holder <NUM> is positioned between the electrode rod <NUM> and the lower clamp <NUM> when viewed from the front-rear direction Y. A V-shaped groove 13a that opens upward is formed on the upper surface of the glass holder <NUM>. The groove 13a extends in the left-right direction X. Relative positions of the glass parts G are determined when the glass parts G of the optical fibers F1 and F2 are placed on the respective grooves 13a of the pair of glass holders <NUM>. Further, a shape of the groove 13a is not limited to the V-shape, and any shape may be used as long as a position of the glass part G can be determined thereby. For example, the groove 13a may be U-shaped or trapezoidal. A material of the glass holder <NUM> is a material capable of withstanding electrical discharge heating such as, for example, a ceramic.

The coated part clamp <NUM> is provided to be rotatable with respect to the lower clamp <NUM>. The coated part clamp <NUM> can open and close an upper surface of the lower clamp <NUM>. The coated part clamp <NUM> can hold the coated part C of the optical fiber F1 or F2 between the coated part clamp <NUM> and the lower clamp <NUM>. Also, the coated part clamp <NUM> can switch between a state in which the optical fiber F1 or F2 is held and a state in which it is not held by opening and closing the upper surface of the lower clamp <NUM>.

As shown in <FIG>, the coated part clamp <NUM> includes a lid member 15a, a compression spring 15b, and a pressing piece 15c. The lid member 15a is rotatable around a rotating shaft 15e. The compression spring 15b and the pressing piece 15c are disposed on an inward side of the lid member 15a. The pressing piece 15c comes into contact with the optical fiber F1 or F2. The compression spring 15b applies a downward biasing force to the pressing piece 15c. Therefore, in a state in which the coated part clamp <NUM> is closed, the pressing piece 15c presses the optical fiber F1 or F2 with a predetermined force due to the compression spring 15b.

A magnet 12a is provided in the lower clamp <NUM>, and an attracted member 15d (such as an iron material) that is magnetically attracted to the magnet 12a is provided in the lid member 15a of the coated part clamp <NUM>. Therefore, in a state in which the coated part clamp <NUM> is close to the upper surface of the lower clamp <NUM>, a downward force (magnetic force) acts on the coated part clamp <NUM>. The magnetic force serves as a force (closing force) acting to close the coated part clamp <NUM>. When the pressing piece 15c presses the optical fiber F1 or F2, the lid member 15a receives an upward reaction force, but the magnetic force of the magnet 12a is set to have a strength such that the lid member 15a is not opened by the reaction force.

A torsion coil spring 15f is disposed near the rotating shaft 15e. The torsion coil spring 15f applies a moment about the rotating shaft 15e in a direction to open the coated part clamp <NUM> to the coated part clamp <NUM>. However, the force (opening force) by which the torsion coil spring 15f tries to open the coated part clamp <NUM> is smaller than the magnetic force (closing force) in a state in which the magnet 12a and the attracted member 15d are close to each other. Therefore, in a state in which the magnet 12a and the attracted member 15d are close to each other, the closing force overcomes the opening force of the torsion coil spring 15f, and the closed state of the coated part clamp <NUM> is maintained.

Here, as shown in <FIG>, the fusion splicer <NUM> of the present embodiment includes a retreat mechanism <NUM> which causes the coated part clamp <NUM> to retreat from the lower clamp <NUM>.

The retreat mechanism <NUM> includes a power source 30a, a gear member <NUM>, an elastic member <NUM>, a transmission part <NUM> (rotating member 33b), and a restricting part <NUM>.

The power source 30a is a motor or the like and includes a pinion gear 30b. The gear member <NUM> (rack member) includes a tooth part 31a and a sliding part 31b. The tooth part 31a is formed in the vertical direction Z and meshes with the pinion gear 30b of the power source 30a. The sliding part 31b slides with respect to a slide guide 2c of the device main body <NUM>. In the present embodiment, the sliding part 31b is a recessed part extending in the vertical direction Z, and the slide guide 2c is fitted in the recessed part. When the sliding part 31b slides with respect to the slide guide 2c, the gear member <NUM> vertically moves with respect to the device main body <NUM>. Further, shapes of the sliding part 31b and the slide guide 2c can be appropriately changed as long as they configure a structure in which the gear member <NUM> vertically moves with respect to the device main body <NUM>.

The transmission part <NUM> of the present embodiment is constituted by a rotating member 33b and a pin 33a.

The rotating member 33b is rotatable around a rotation center 33c. The rotating member 33b includes a first arm 33d and a second arm 33e. The first arm 33d is close to or in contact with a lower end of the pin 33a. The second arm 33e is close to or in contact with the restricting part <NUM>. The pin 33a is slidably movable in the vertical direction Z. Sliding of the pin 33a is guided by a guide member (not shown).

The elastic member <NUM> is elastically deformed by power received from the power source 30a. Due to the elastically deformation of the elastic member <NUM>, the elastic member <NUM> stores elastic energy (restorative force). The elastic member <NUM> is deformed to be restored when restriction on rotation of the rotating member 33b is released by the restricting part <NUM>. The elastic member <NUM> rotates the rotating member 33b by the restorative force in accordance with restoring deformation of the elastic member <NUM>.

Although the elastic member <NUM> of the present embodiment is a tension spring, other members having elasticity (such as a rubber) may be used as the elastic member <NUM>. A first end (lower end) of the elastic member <NUM> is locked to the gear member <NUM>, and a second end (upper end) thereof is locked to a portion between the rotation center 33c and the second arm 33e of the rotating member 33b.

The restricting part <NUM> is fixed to the windproof cover <NUM>. The restricting part <NUM> is disposed to sandwich the transmission part <NUM> between the restricting part <NUM> and the coated part clamp <NUM> in the front-rear direction Y. In a state in which the windproof cover <NUM> is closed, rotation of the rotating member 33b is restricted when the restricting part <NUM> comes into contact with the second arm 33e. On the other hand, as shown in <FIG>, in a state in which the windproof cover <NUM> is open, since the restricting part <NUM> retreats from the second arm 33e, rotation of the rotating member 33b is allowed. That is, the restricting part <NUM> restricts rotation of the rotating member 33b in a state in which the windproof cover <NUM> is closed and releases the restriction when the windproof cover <NUM> is open. In other words, the restricting part <NUM> restricts rotation of the rotating member 33b while the elastic member <NUM> stores elastic energy (while the elastic member <NUM> is elastically deformed by power received from the power source 30a). The restricting part <NUM> releases the elastic energy stored in the elastic member <NUM> in conjunction with an opening operation of the windproof cover <NUM>, thereby releases restriction on rotation of the rotating member 33b. According to the release of the restriction, the restricting part <NUM> causes the elastic member <NUM> to be deformed and restored and causes the rotating member 33b to rotate by the restorative force generated from the elastic member <NUM>.

Next, an operation of the fusion splicer <NUM> configured as described above will be described.

At the time of fusing-splicing the optical fibers F1 and F2 using the fusion splicer <NUM>, a state in which the windproof cover <NUM> is open and the coated part clamp <NUM> is open is set. In this state, the optical fibers F1 and F2 are placed on the lower clamps <NUM> and the glass holders <NUM>. More specifically, the coated parts C of the optical fibers F1 and F2 are placed on the lower clamps <NUM>, and the glass parts G are placed in the grooves 13a of the glass holders <NUM>. Further, the optical fibers F1 and F2 are each put into a state in which a portion of the coated part C is removed in advance and the glass part G is exposed.

Next, the windproof cover <NUM> and the coated part clamp <NUM> are closed. Therefore, the state shown in <FIG> is obtained.

Next, the movable stages <NUM> are moved in the left-right direction X so that the glass parts G of the optical fibers F1 and F2 are made to abut against each other, and electric power is supplied to the heaters 2a (the electrode rods <NUM>). Therefore, the glass parts G of the optical fibers F1 and F2 are melted, integrated, and fusion-spliced.

Here, in the present embodiment, the power source 30a is driven after the windproof cover <NUM> and the coated part clamp <NUM> are closed. When the power source 30a is driven to rotate the pinion gear 30b, the gear member <NUM> moves downward, and the elastic member <NUM> is elastically deformed to extend downward. At this time, rotation of the rotating member 33b around the rotation center 33c is restricted by the restricting part <NUM>. Therefore, the elastic member <NUM> continues to be pulled downward while the rotating member 33b does not rotate, and elastic energy is gradually stored in the elastic member <NUM>. The elastic energy stored in the elastic member <NUM> is used to open the coated part clamps <NUM>.

When the windproof cover <NUM> is opened manually or automatically after the fusion splicing is completed, the restricting part <NUM> retreats from the rotating member 33b and the rotating member 33b reaches a state in which it can rotate as shown in <FIG>. Therefore, the elastic energy stored in the elastic member <NUM> is released in a short period of time, and the rotating member 33b vigorously rotates around the rotation center 33c as shown in <FIG>. Then, the first arm 33d of the rotating member 33b pushes the pin 33a upward. Also, since the pin 33a pushes the lid member 15a of the coated part clamp <NUM> upward, the lid member 15a rotates around the rotating shaft 15e, and a distance between the attracted member 15d and the magnet 12a increases. Since a magnetic force decreases as the magnet 12a and the attracted member 15d move away from each other, when the coated part clamp <NUM> is opened to a certain extent, an opening force of the torsion coil spring 15f overcomes a closing force, and the coated part clamp <NUM> is opened.

Thereafter, when the windproof cover <NUM> is released as shown in <FIG>, a user can pull out the fusion-spliced optical fibers F1 and F2. After the windproof cover <NUM> is opened, an operation of returning the gear member <NUM> to the position shown in <FIG> may be performed by rotating the power source 30a in a reverse direction and moving the gear member <NUM> upward. Alternatively, when the coated part clamp <NUM> is closed, since the rotating member 33b rotates to pull the elastic member <NUM> upward, the gear member <NUM> may be returned to the position shown in <FIG> using the pulling-up force.

When the fusion splicing is performed again, the operation returns to the state shown in <FIG> by setting the optical fibers F1 and F2 and closing the coated part clamps <NUM> and the windproof cover <NUM>.

As described above, the fusion splicer <NUM> of the present embodiment includes the heater 2a which heats the glass parts G of the optical fibers F1 and F2, the lower clamp <NUM> on which the coated part C of the optical fiber F1 or F2 is placed, the coated part clamp <NUM> which sandwiches the optical fiber F1 or F2 between the coated part clamp <NUM> and the lower clamp <NUM>, the windproof cover <NUM> which covers the heater 2a and the coated part clamp <NUM>, and the retreat mechanism <NUM> which causes the coated part clamp <NUM> to retreat from the lower clamp <NUM>. The retreat mechanism <NUM> includes the power source 30a, the elastic member <NUM> that is elastically deformed by power received from the power source 30a, the transmission part <NUM> that pushes the coated part clamp <NUM> upward due to an elastic force received from the elastic member <NUM>, and the restricting part <NUM> which restricts displacement of the transmission part <NUM> in a state in which the windproof cover <NUM> is closed. Then, the restricting part <NUM> releases restriction on displacement of the transmission part <NUM> in conjunction with an opening operation of the windproof cover <NUM>.

According to such a configuration, the elastic member <NUM> can be elastically deformed by driving the power source 30a after the optical fibers F1 and F2 are set and the windproof cover <NUM> and the coated part clamp <NUM> are closed. Then, since restriction on displacement of the transmission part <NUM> is released in conjunction with an opening operation of the windproof cover <NUM> after the fusion splicing is completed, the transmission part <NUM> can be displaced and the coated part clamp <NUM> can be pushed upward by the elastic force received from the elastic member <NUM>. As described above, power of the power source 30a is not simply transmitted to the coated part clamp <NUM> via a gear or the like, but the power is temporarily stored in the elastic member <NUM> as elastic energy and then transmitted to the coated part clamp <NUM>, and thus an operation time at the time of opening the coated part clamp <NUM> can be shortened. Also, when power obtained from the power source 30a is stored in the elastic member <NUM> using a time while the fusion splicing or the like is performed and then is released in a short period of time, the coated part clamp <NUM> can be opened by overcoming a closing force of the coated part clamp <NUM> while using a low-output power source 30a.

Also, the transmission part <NUM> of the present embodiment includes the rotating member 33b which is rotatable around the rotation center 33c, and the pin 33a positioned between the coated part clamp <NUM> and the rotating member 33b and slidably movable in the vertical direction Z. When the rotating member 33b rotates due to an elastic force received from the elastic member <NUM>, the pin 33a slides upward and pushes the coated part clamp <NUM> upward. As described above, when rotational displacement of the rotating member 33b is converted into upward displacement of the pin 33a, the coated part clamp <NUM> can be more reliably opened. Also, when a distance between the rotation center 33c and the lower end of the pin 33a is made smaller than a distance between the rotation center 33c and an upper end of the elastic member <NUM>, a force by which the pin 33a moves upward can also be amplified by the lever ratio.

Furthermore, as shown in <FIG>, according to the action of the restricting part <NUM> and the rotating member 33b, a state of the windproof cover <NUM> is gradually changed from a closed state to an open state (release state). In accordance with the foregoing change in state of the windproof cover <NUM>, the glass clamps <NUM> attached to the inner surface of the windproof cover <NUM> automatically moves upward separately from the optical fibers F1 and F2, and the coated part clamps <NUM> also automatically opens. As the windproof cover <NUM> rotates around the rotation center 3a and the coated part clamps <NUM> rotate around the rotating shaft 15e, the windproof cover <NUM>, the glass clamps <NUM>, and the coated part clamps <NUM> each move to a position apart from an upper space of the lower clamp <NUM>. Therefore, a state in which there no member covering over the optical fibers F1 and F2 from above is obtained, and a state in which an upper space of the optical fibers F1 and F2 is automatically released is obtained. Since the state in which there no member covering over the optical fibers F1 and F2 from above is obtained, a user can easily remove the fusion-spliced optical fibers F1 and F2. Particularly, the user is not necessary to carry out an operation of individually opening the glass clamps <NUM> and the coated part clamps <NUM> as an operation different from an operation of opening the windproof cover <NUM>, and it is possible to easily remove the optical fibers F1 and F2 that were fusion-spliced to each other only by carrying out the operation of opening the windproof cover <NUM>. Consequently, it is possible to reduce the number of operation steps carried out by the user. Accordingly, it is possible to achieve the fusion splicer that contributes to reduction in the number of operation steps.

Next, a second embodiment according to the invention will be described, but basic configurations are the same as those in the first embodiment. Therefore, constituents which are the same are denoted by the same reference numerals, a description thereof will be omitted, and only different points will be described.

In the present embodiment, a configuration of a transmission part <NUM> is different from that in the first embodiment. As shown in <FIG>, the transmission part <NUM> of the present embodiment includes a rotating member 33b but does not include the pin 33a (see <FIG>). Also, a shape of the rotating member 33b is different from that of the first embodiment.

The rotating member 33b of the present embodiment is formed in an L shape when viewed from a left-right direction X. Although not shown, when the rotating member 33b is rotated by an elastic force received from an elastic member <NUM>, a first arm 33d of the rotating member 33b directly pushes the coated part clamp <NUM> upward. Even with such a configuration, an operation time at the time of opening a coated part clamp <NUM> can be shortened while using a low-output power source 30a.

Next, a third embodiment according to the invention will be described, but basic configurations are the same as those in the second embodiment. Therefore, constituents which are the same are denoted by the same reference numerals, a description thereof will be omitted, and only different points will be described.

As shown in <FIG>, a fusion splicer <NUM> of the present embodiment includes an opening/closing mechanism <NUM> for automatically opening and closing a windproof cover <NUM>. The opening/closing mechanism <NUM> includes a cover driver 40a, a geared pulley <NUM>, a belt <NUM>, and a connecting pulley <NUM>. The cover driver 40a is a motor or the like. The cover driver 40a includes a pinion gear 40b. The geared pulley <NUM> includes a gear part 41a and a pulley part 41b. The gear part 41a meshes with the pinion gear 40b of the cover driver 40a, and one end (lower end) of the belt <NUM> is wrapped around the pulley part 41b. The belt <NUM> may be a timing belt, and the pulley part 41b may be a timing pulley.

The other end (upper end) of the belt <NUM> is wrapped around a pulley part 43a of the connecting pulley <NUM>. Also, the connecting pulley <NUM> is fixed to the windproof cover <NUM>. With this configuration, the connecting pulley <NUM> connects the belt <NUM> and the windproof cover <NUM>, and when the cover driver 40a is driven, the windproof cover <NUM> rotates around a rotation center 3a.

According to the present embodiment, the windproof cover <NUM> is automatically opened by driving of the opening/closing mechanism <NUM>.

Then, a restricting part <NUM> fixed to the windproof cover <NUM> releases restriction on displacement of the transmission part <NUM> in conjunction with an opening operation of the windproof cover <NUM>, and the coated part clamp <NUM> is opened by the displacement of the transmission part <NUM>. Accordingly, the windproof cover <NUM> and the coated part clamp <NUM> are automatically opened, and thus operability can be further improved from a user's point of view.

Further, the opening/closing mechanism <NUM> of the present embodiment is an example, and other configurations may also be employed as long as the windproof cover <NUM> can be automatically opened and closed.

Next, a fourth embodiment according to the invention will be described, but basic configurations are the same as those in the third embodiment. Therefore, constituents which are the same are denoted by the same reference numerals, description thereof will be omitted, and only different points will be described.

As shown in <FIG>, a fusion splicer <NUM> of the present embodiment includes a second opening/closing mechanism <NUM>. Also, the windproof cover <NUM> is constituted by a first segmented member 3b driven by an opening/closing mechanism <NUM> and a second segmented member 3c driven by the second opening/closing mechanism <NUM>. The first segmented member 3b is rotatable around a rotation center 3a, and the second segmented member 3c is rotatable around a second rotation center 3d.

The second opening/closing mechanism <NUM> includes a second cover driver 50a, a second geared pulley <NUM>, a second belt <NUM>, and a second connecting pulley <NUM>. The second cover driver 50a is a motor or the like. The second cover driver 50a includes a second pinion gear 50b. The second geared pulley <NUM> includes a second gear part 51a and a second pulley part 51b. The second gear part 51a meshes with the second pinion gear 50b, and one end (lower end) of the second belt <NUM> is wrapped around the second pulley part 51b. The second belt <NUM> may be a timing belt, and the second pulley part 51b may be a timing pulley.

The other end (upper end) of the second belt <NUM> is wrapped around a pulley part 53a of the second connecting pulley <NUM>. Also, the second connecting pulley <NUM> is fixed to the second segmented member 3c of the windproof cover <NUM>. With this configuration, the second connecting pulley <NUM> connects the second belt <NUM> and the second segmented member 3c, and when the second cover driver 50a is driven, the second segmented member 3c rotates around the second rotation center 3d.

According to the present embodiment, the second segmented member 3c is automatically opened by driving of the second opening/closing mechanism <NUM>. Then, a restricting part <NUM> fixed to the second segmented member 3c releases restriction on displacement of a transmission part <NUM> in conjunction with an opening operation of the second segmented member 3c, and a coated part clamp <NUM> is opened by the displacement of the transmission part <NUM>. Even with such a configuration, operability can be improved.

Next, a fifth embodiment according to the invention will be described, but basic configurations are the same as those in the fourth embodiment. Therefore, constituents which are the same are denoted by the same reference numerals, description thereof will be omitted, and only different points will be described.

As shown in <FIG>, a fusion splicer <NUM> of the present embodiment includes a retreat mechanism <NUM>. The retreat mechanism <NUM> has both functions of the second opening/ closing mechanism <NUM> and a retreat mechanism <NUM> in the fourth embodiment.

The retreat mechanism <NUM> includes a power source 60a, a gear member <NUM>, a first wire <NUM>, an elastic member <NUM>, a second wire <NUM>, a rotating pulley <NUM>, a torsion coil spring <NUM>, a transmission part <NUM>, and a restricting part <NUM>.

The power source 60a is a motor or the like and includes a pinion gear 60b. The gear member <NUM> meshes with the pinion gear 60b of the power source 60a. A locking part 61a is formed on a side surface of the gear member <NUM>, and a lower end of the first wire <NUM> is locked to the locking part 61a. Also, the gear member <NUM> has a first winding surface 61b, and when the gear member <NUM> rotates, the first wire <NUM> is wound on the first winding surface 61b. An upper end of the first wire <NUM> is fixed to a lower end of the elastic member <NUM>.

The elastic member <NUM> is elastically deformed by power received from the power source 60a. Although the elastic member <NUM> of the present embodiment is a tension spring, other members having elasticity (such as a rubber) may be used as the elastic member <NUM>. An upper end of the elastic member <NUM> is fixed to one end of the second wire <NUM>. The rotating pulley <NUM> is fixed to a second segmented member 3c of a windproof cover <NUM>. A locking part 65a is formed on a side surface of the rotating pulley <NUM>, and the other end of the second wire <NUM> is locked to the locking part 65a. Also, the rotating pulley <NUM> has a second winding surface 65b, and a portion of the second wire <NUM> is wound on the second winding surface 65b.

The torsion coil spring <NUM> is positioned near a central axis of the rotating pulley <NUM> and applies a moment in a direction to close the second segmented member 3c with respect to the rotating pulley <NUM>. The moment of the torsion coil spring <NUM> is transmitted to the second segmented member 3c via the rotating pulley <NUM>. However, in a state in which a first segmented member 3b is closed, since rotation of the second segmented member 3c is restricted by the restricting part <NUM>, a state in which the second segmented member 3c is closed is maintained.

The transmission part <NUM> of the present embodiment is constituted by a rotating member 67a and the second segmented member 3c. The rotating member 67a is rotatable around a rotation center 67c. The rotating member 67a is formed in substantially an L shape when viewed from a left-right direction X and includes a first arm 67d and a second arm 67e. The first arm 67d is in contact with or close to a coated part clamp <NUM> from below. The second arm 67e is in contact with or close to an interlocking part 67b formed in the second segmented member 3c.

The interlocking part 67b extends downward from the second segmented member 3c. Also, a restricted part 67f is formed in the second segmented member 3c. The restricted part 67f protrudes in a front-rear direction Y from the interlocking part 67b. Further, a protrusion <NUM> that protrudes upward is formed at a distal end portion of the restricted part 67f in the front-rear direction Y. The restricted part 67f is in contact with or close to the restricting part <NUM> from below. The restricting part <NUM> is sandwiched between the protrusion <NUM> and the interlocking part 67b in the front-rear direction Y.

The restricting part <NUM> protrudes downward from the first segmented member 3b and is fixed to the first segmented member 3b. In a state in which the first segmented member 3b and the second segmented member 3c are closed, the restricting part <NUM> comes into contact with the restricted part 67f from above, and thereby rotation of the second segmented member 3c around a second rotation center 3d is restricted.

Next, an operation of the fusion splicer <NUM> of the present embodiment will be described.

When the optical fibers F1 and F2 are set and the coated part clamps <NUM>, the first segmented member 3b, and the second segmented member 3c are closed, the state shown in <FIG> is obtained. In the present embodiment, the power source 60a is driven after the first segmented member 3b and the second segmented member 3c are closed. When the power source 60a is driven, the gear member <NUM> rotates and the first wire <NUM> is wound on the first winding surface 61b. Therefore, the elastic member <NUM> and the second wire <NUM> are pulled downward, and a rotational force acts on the rotating pulley <NUM> in a direction to open the second segmented member 3c.

Since the rotating pulley <NUM> is connected to the second segmented member 3c, the second segmented member 3c also tries to open, but rotation of the second segmented member 3c is restricted by the restricting part <NUM>. Therefore, as shown in <FIG>, the elastic member <NUM> continues to be pulled downward while the second segmented member 3c and the rotating pulley <NUM> do not rotate and the rotating member 67a does not rotate, and elastic energy is gradually stored in the elastic member <NUM>.

After the fusion splicing is completed, when a cover driver 40a is driven and the first segmented member 3b is opened, the restricting part <NUM> retreats from the restricted part 67f as shown in <FIG> and the second segmented member 3c becomes a state in which it can rotate. Therefore, the elastic energy stored in the elastic member <NUM> is released in a short period of time, and the second segmented member 3c is vigorously opened as shown in <FIG>. At this time, the interlocking part 67b of the second segmented member 3c pushes the second arm 67e of the rotating member 67a, and thereby the rotating member 67a rotates around the rotation center 67c. Then, the first arm 67d of the rotating member 67a pushes the coated part clamp <NUM> upward. Since a magnetic force decreases as a magnet 12a and an attracted member 15d move away from each other, when the coated part clamp <NUM> is opened to a certain extent, an opening force of the torsion coil spring 15f overcomes a closing force of the magnet 12a, and the coated part clamp <NUM> is opened.

As described above, the fusion splicer <NUM> of the present embodiment includes the heater 2a which heats the glass parts G of the optical fibers F1 and F2, the lower clamp <NUM> on which the optical fiber F1 or F2 is placed, the coated part clamp <NUM> which sandwiches the optical fiber F1 or F2 between the coated part clamp <NUM> and the lower clamp <NUM>, the windproof cover <NUM> which covers the heater 2a and the coated part clamp <NUM>, and the retreat mechanism <NUM> which causes the coated part clamp <NUM> to retreat from the lower clamp <NUM>. The retreat mechanism <NUM> includes the power source 60a, the elastic member <NUM> that is elastically deformed by power received from the power source 60a, the transmission part <NUM> that pushes the coated part clamp <NUM> upward due to an elastic force received from the elastic member <NUM>, and the restricting part <NUM> which restricts displacement of the transmission part <NUM> in a state in which the windproof cover <NUM> (the first segmented member 3b and the second segmented member 3c) is closed. Then, The restricting part <NUM> releases restriction on displacement of the transmission part <NUM> in conjunction with an opening operation of the windproof cover <NUM>. With such a configuration, the same operation and effect as those of the first embodiment can be obtained.

Further, in the present embodiment, the windproof cover <NUM> is constituted by the first segmented member 3b driven by the opening/closing mechanism <NUM> and the second segmented member 3c driven by the power source 60a.

Power of the power source 60a is transmitted to the second segmented member 3c via the elastic member <NUM>. Then, the restricting part <NUM> fixed to the first segmented member 3b releases restriction on displacement of the transmission part <NUM> in conjunction with an opening operation of the first segmented member 3b. With this configuration, the coated part clamp <NUM> is opened in conjunction with an operation of the opening/closing mechanism <NUM> opening the first segmented member 3b, and thereby operability is improved. Also, since the power for opening the second segmented member 3c and the power for elastically deforming the elastic member <NUM> are obtained by the common power source 60a, increase in the number of actuators such as motors can be avoided.

Also, since the second arm 67e is longer than the first arm 67d, a force when the interlocking part 67b pushes the rotating member 67a can be amplified by the lever ratio and then transmitted to the coated part clamp <NUM>. Therefore, even when a closing force (magnetic force of the magnet 12a) of the coated part clamp <NUM> is large, the coated part clamp <NUM> can be more reliably opened.

Further, the technical scope of the invention is not limited to the above-described embodiments, and various modifications can be made.

For example, the coated part clamp <NUM> and the lower clamp <NUM> in the first to fifth embodiments may be a portion of a detachable-type fiber holder. In this case, the lower clamp <NUM> is a main body of the fiber holder, and the coated part clamp <NUM> is attached to the main body to be openable and closable.

When a detachable-type fiber holder is employed, the optical fiber F1 or F2 is sandwiched by the fiber holder outside the device main body <NUM>, and in this state, a portion of the coated part C can be removed and the optical fiber F1 or F2 can be cut by a predetermined length. Then, the optical fiber F1 or F2 can be mounted to the device main body <NUM> together with the fiber holder in a state in which the glass portion G is exposed by a predetermined length.

Also, since the fusion splicer <NUM> of the first to fifth embodiments includes two coated part clamps <NUM>, two retreat mechanisms <NUM> and <NUM> may be provided to open the respective coated part clamps <NUM>. In this case, the two retreat mechanisms <NUM> and <NUM> in each embodiment may be disposed at a distance in the left-right direction X.

Alternatively, for example, the rotating member 33b or 67a may be configured to be long in the left-right direction X so that the two coated part clamps <NUM> are opened by one rotating member 33b or 67a. In this case, the two coated part clamps <NUM> can be opened by one retreat mechanism <NUM> or <NUM>.

Further, in the case of the first embodiment, it may be configured such that two pins 33a are pushed upward by one rotating member 33b. In this case, in the retreat mechanism <NUM>, only the number of pins 33a is set to two, and the two pins 33a need only be disposed at positions corresponding to the two coated part clamps <NUM>.

Claim 1:
A fusion splicer (<NUM>) comprising:
a heater (2a) which heats a glass part (G) of an optical fiber (F1, F2);
a lower clamp (<NUM>) on which a coated part (C) of the optical fiber is placed:
a coated part clamp (<NUM>) which sandwiches the optical fiber between the coated part clamp and the lower clamp;
a windproof cover (<NUM>) which covers the heater and the coated part clamp:
a retreat mechanism (<NUM>, <NUM>) which causes the coated part clamp to retreat from the lower clamp;
an opening/closing mechanism (<NUM>) which drives the windproof cover; and
a pair of glass clamps (<NUM>) which are attached to an inner surface of the windproof cover, wherein
the retreat mechanism comprises:
a power source (30a, 60a);
a rotating member (33b, 67a) which is rotatable around a rotation center (33c, 67c);
an elastic member (<NUM>, <NUM>) that elastically deforms by power received from the power source and thereby stores elastic energy;
a transmission part (<NUM>, <NUM>) which pushes the coated part clamp upward due to an elastic force received from the elastic member; and
a restricting part (<NUM>, <NUM>) which restricts rotation of the rotating member while the elastic member stores the elastic energy in a state in which the windproof cover is closed, and wherein
the restricting part releases the elastic energy stored in the elastic member and thereby releases restriction on rotation of the rotating member in conjunction with an opening operation of the windproof cover.