JP2013037173A - Adapter identifying jig - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an adapter identifying jig which allows easy and reliable specification of an optical connector adapter as an object of inserting/extracting work even in the case that arrays of optical connector adapters are disposed in order in a depth direction from the front of a box and the number of optical connector adapters to be provided in an optical patch panel is large.SOLUTION: An adapter identifying jig 31 is inserted between arbitrary laminated optical connector adapters 23 throughout arrays to divide the arrays, and positional relations between optical connector adapters 23 arrayed along a plate surface at the division position are identified. That is, adapter identification numbers 1 to 12 of optical connector adapters 23 located on the front side out of the optical connector adapters 23 arrayed along the plate surface 23 can be easily visually confirmed, so that optical connector adapters 23 in arrays on the deep side can be specified in relation to the optical connector adapters 23 on the front side, the adapter identification numbers of which can be recognized, on the basis of relations between respective optical connector adapters 23 arrayed in respective arrays.

Description

  The present invention relates to an adapter identification jig for identifying optical connector adapters arranged in an optical patch panel.

  As shown in the perspective view of FIG. 1, optical connector adapters 2 are arranged in an orderly manner on the optical patch panel 1 in the optical connection box. Conventionally, in order to identify the optical connector adapter 2, a number label 3 on which the identification number of the optical connector adapter 2 is written is attached to the panel surface of the optical patch panel 1 near the optical connector adapter 2. When the connector 5 provided at the end of the optical fiber cord 4 is inserted and removed, the corresponding optical connector adapter 2 is specified by confirming the identification number shown on the number label 3.

  The optical connection box is small, and as the number of optical connector adapters 2 increases, the number of optical fiber cords 4 coming out from the optical connector adapter 2 increases, and the identification number shown on the number label 3 is visually confirmed. It becomes difficult. In addition, the optical connection box is generally configured in a rectangular parallelepiped box, and the connector connecting portions of many optical fiber cords 4 are housed in a small box. It arrange | positions in the depth direction and makes the insertion / extraction direction of the connector 5 the width direction of a box. For this reason, the optical connector adapter 2 is disposed in the depth direction from the front of the box, and the identification number of the frontmost optical connector adapter 2 on the front side can be easily visually confirmed. However, the identification number of the optical connector adapter 2 arranged in the back is structurally hidden behind the optical fiber cord 4 and is difficult to visually confirm. Accordingly, the parts other than the optical connector adapter 2 on the front side are checked by looking directly from the side of the box. However, the closer to the back side, the more difficult it is to visually check and the accuracy of the connector insertion / removal operation is lost.

  Patent Document 1 discloses a connector work auxiliary tool capable of efficiently attaching and detaching an optical connector plug to and from an optical connector adapter in an adapter array portion in which optical connector adapters are provided in upper and lower stages. This auxiliary tool for connector work is provided with a pair of extending sheet parts extending from both side walls of the portal-shaped head part, which can accommodate an optical connector adapter, and one or the other of the pair of extending sheet parts, Wire number indications corresponding to the plug holes of the multi-stage optical connector adapter are provided.

JP 2008-224891 A

  However, the connector work auxiliary tool disclosed in the above-mentioned conventional Patent Document 1 is used by approaching the panel surface from the front surface side of the adapter array portion and housing the optical connector adapter to be worked in the head portion. . For this reason, when the optical connector adapters are arranged in the depth direction from the front of the box and the connector insertion / removal direction is the width direction of the box, if there are many optical fiber cords, the optical fiber cords obstruct the connector work. It becomes difficult to store the optical connector adapter to be worked in the head part of the auxiliary tool. Moreover, even if the optical connector adapter to be worked can be accommodated in the head portion, it is possible to visually check the wire number indication provided on one or the other of the pair of extending sheet portions. It is difficult to get in the way. Therefore, it is difficult to specify the optical connector adapter to be worked that is arranged at the back of the box.

  In addition, the connector working auxiliary tool disclosed in the above-described conventional Patent Document 1 is configured by bending and molding a resin sheet having a complicated shape, which is expensive to manufacture.

The present invention has been made to solve such problems,
An adapter identification jig for identifying single-core optical connector adapters that are fitted with play in the row direction in the openings formed in a plurality of rows on the optical patch panel and stacked in a plurality of rows,
It has a plate shape and is inserted between each optical connector adapter in a stacked manner so as to divide each row and identify the positional relationship between the optical connector adapters arranged along the plate surface of the divided portion. It is characterized by that.

  According to this configuration, single optical connector adapters are fitted in a plurality of rows with play in the row direction in the openings formed in the optical patch panel side by side in a plurality of rows. Therefore, each optical connector adapter is allowed to idle in the row direction in each laminated opening, and a plate-shaped adapter identification jig can be inserted across each row between any laminated optical connector adapters. Therefore, when the optical connector adapter row is arranged in the depth direction from the front of the box and the connector insertion / removal direction is the width direction of the box, even if there are many optical fiber cords provided on the optical patch panel, Push the front end of the plate-shaped adapter identification jig between any optical connector adapters in the row where the side identification number can be easily visually confirmed. By inserting the longitudinal end of the back side between the optical connector adapters in the back row, an adapter identification jig can be inserted across each row between the stacked optical connector adapters to divide each row I can do it. The optical connector adapters in the back row can be identified by identifying the positional relationship between the optical connector adapters arranged along the plate surface of the adapter identification jig at the divided location. In other words, among the optical connector adapters lined up along the plate surface of the adapter identification jig at the divided location, the optical connector adapter on the front side can be easily visually confirmed with the identification number, so it is arranged in each row. The optical connector adapter in the back row can be identified from the relationship with the optical connector adapter on the near side where the identification number can be grasped based on the previously recognized relationship between the optical connector adapters.

  Therefore, even when the optical connector adapter row is arranged in the depth direction from the front of the box, and there are many optical connector adapters and optical fiber cords provided on the optical patch panel, the optical connector adapters to be inserted and removed can be easily and reliably. It becomes possible to specify. In addition, since one optical connector adapter group and the optical fiber cord group divided by the adapter identification jig are hidden behind the adapter identification jig and cannot be touched, there is a risk that an optical connector plug that is not a work target will be erroneously gripped when the optical connector plug is inserted or removed. In addition, the optical connector plug insertion / extraction operation is not obstructed by the optical connector adapter group and the optical fiber cord group that are not the object of operation. As a result, the workability of the optical connector plug insertion / extraction work is improved. In addition, since each optical connector adapter can be identified even if a large number of optical connector adapters are arranged, the optical patch panel can be made smaller. Further, since the adapter identification jig is simply constituted by a plate-like member, the cost for manufacturing the adapter identification jig is reduced.

  Further, the present invention is characterized in that a window is formed that faces the panel surface of the optical patch panel that is inserted over each row and is hidden by the plate surface when each row is divided.

  According to this configuration, the panel surface of the optical patch panel that is inserted over each row and is hidden on the plate surface of the adapter identification jig when each row is divided is visible from the window formed in the adapter identification jig. For this reason, in addition to the positional relationship between the optical connector adapters arranged along the plate surface of the adapter identification jig at the divided location, the light attached to the panel surface of the optical patch panel that is visible from the window of the adapter identification jig Since the positional relationship with the connector adapter is also grasped, it is possible to more easily identify the optical connector adapter to be worked.

  Further, the present invention is characterized in that the identification number of the optical connector adapter is represented on the plate surface corresponding to the laminated position of the optical connector adapter.

  According to this configuration, when specifying the optical connector adapter in the back row from the relationship with the optical connector adapter on the near side where the identification number can be grasped, the plate surface corresponding to the stacking position of the optical connector adapter is used. By referring to the identification number of the optical connector adapter shown, it is possible to easily identify the optical connector adapter in the back row based on the relationship between the optical connector adapters arranged in each row. I can do it.

  The present invention is also characterized in that the optical patch panel connects optical connector plugs to each other via an optical connector adapter in an optical connection box.

  According to this structure, the adapter identification jig | tool which can identify the optical connector adapter in the optical patch panel in an optical junction box easily and reliably is provided.

  According to the present invention, as described above, even when the row of optical connector adapters is arranged in the depth direction from the front of the box and there are many optical connector adapters and optical fiber cords provided on the optical patch panel, It is possible to provide an adapter identification jig capable of easily and reliably specifying an optical connector adapter to be performed.

It is a perspective view of the conventional optical patch panel in an optical junction box. It is a figure which shows the external appearance of the optical connection box which accommodates the optical patch panel to which the adapter identification jig | tool by one embodiment of this invention is applied. It is a figure which shows the internal state which removed the cover of the optical junction box shown in FIG. It is a perspective view which expands and shows a part of optical patch panel in the optical junction box shown in FIG. It is a figure which shows the adapter identification jig | tool by one embodiment of this invention. FIG. 6 is a perspective view showing a state where the adapter identification jig shown in FIG. 5 is inserted into the optical patch panel shown in FIG. 4. FIG. 7 is a partially enlarged perspective view showing an insertion state of the adapter identification jig shown in FIG. 6.

  Next, an embodiment in which the adapter identification jig according to the present invention is applied to an optical patch panel in an optical junction box will be described.

  2A is a side view of the optical junction box 11 in the present embodiment, FIG. 2B is a front view, and FIG. 2C is a bottom view.

  The optical connection box 11 is configured by covering a flat resin body 11a with a box-shaped resin cover 11b. The external dimensions are height (vertical) 450 mm, width (horizontal) 350 mm, and depth (thickness) 160 mm, and an opening 11 c is provided on the bottom surface of the cover 11 b. The opening 11 c serves as an introduction portion for an external optical fiber cable introduced into the optical connection box 11 and a lead-out portion for a local optical fiber cord led out from the optical connection box 11.

  FIG. 3A is a front view of the optical junction box 11 with the cover 11b removed, and FIG. 3B is a right side view thereof.

  A metal base plate 12 whose outer periphery is slightly smaller on the surface of the body 11a is provided. A fusion splicing unit 13 is provided on the lower side of the base plate 12, and a connector connection unit 14 is provided on the upper side. . The fusion splicing unit 13 and the connector connecting unit 14 are mounted on the pull-out tables 15 and 16, respectively, and are pulled out freely in a direction perpendicular to the plate surface of the base plate 12 by placing the hand on the pulling portions 15a and 16b. It is possible. The pull-out tables 15 and 16 indicated by dotted lines in FIG. 5B show a state of being pulled out from the base plate 12.

  An external optical fiber cable 17 is introduced into the lower end of the base plate 12 cut out in a rectangular shape via the opening 11c. In the present embodiment, the external optical fiber cable 17 is a tape slot type in which a plurality of 4-core tape cores are accommodated in a spacer groove around the tension member. A total of 48 optical fiber cords are taken out by the core tape core wire 18. The taken-out four-fiber ribbon 18 is preliminarily used as an optical junction box 11 for relaying between the fusion splicing unit 13 and the connector connecting unit 14 in the two splice trays 13a constituting the fusion splicing unit 13. Are fused and connected to one end of a four-fiber FO (fan-out) cord 19 wired to the cable. At the time of this fusion splicing, the fusion splicing unit 13 is pulled out to the position indicated by the dotted line in FIG. 5B by the pull-out table 15, and the lid of the splice tray 13a is opened as indicated by the dotted line in FIG. . Seven splicing cores 18 are guided to one splice tray 13a to accommodate 28 optical fiber fusion splicing portions, and the five splicing trays 13a have five four-fiber ribbons 18 to each other. The 20-fiber optical fiber fusion splicing part is accommodated.

  A total of 48 cores of the four-fiber FO cord 19 whose one end is fusion-connected are led to the connector connecting unit 14 via the cord tray 21 in advance. An SC-type optical connector plug 20 is attached to the other end of the four-fiber FO cord 19, and a total of 48 optical connector plugs 20 are attached to the optical patch panel 22, for a total of 48 SC-type single cores. It is inserted in advance on one side of the optical connector adapter 23. The optical patch panel 22 constitutes a connector connection unit 14 together with the optical connector adapter 23, and is formed by bending the lower end of a metal plate into an L shape, and the bent portion is fixed to the pull-out table 16. Yes. As shown in FIG. 1B, twelve optical connector adapters 23 are arranged in one row, and a total of 48 optical connector adapters 23 are arranged in four rows in the depth direction, compared with the conventional case of 24 shown in FIG. And high density. On the other side of the optical connector adapter 23, an SC-type optical connector plug 25 attached to one end of a local optical fiber cord 24 indicated by a dotted line in FIG. The optical patch panel 22 connects the optical connector plugs 20 and 25 through the optical connector adapter 23 in the optical connection box 11, and the local optical fiber cord 24 is connected to the FO cord 19 by a connector. By this connector connection, the local optical fiber cord 24 is optically connected to the tape core wire 18 in the external optical fiber cable 17 via the FO cord 19. The other end side of the in-house optical fiber cord 24 with one end inserted into the optical connector adapter 23 is routed to the lower end side of the base plate 12, and is led out of the optical connection box 11 through the opening 11c. Wiring connection is made to the optical equipment provided.

  FIG. 4 is a perspective view showing a state where the optical connector plug 25 of the local optical fiber cord 24 is inserted into the optical connector adapter 23 provided on the optical patch panel 22. In the figure, the same or corresponding parts as in FIG.

  The optical patch panel 22 is formed with elongated holes (not shown) arranged in parallel in four rows in the vertical direction. The dimension in the height direction of each opening is slightly larger than the height dimension in which twelve panel-mounted single-fiber optical connector adapters 23 are stacked, and is set to be equal in each opening. Therefore, 48 single-fiber optical connector adapters 23 are fitted into each opening 12 in a row in the row direction, and are stacked in four rows. On the panel surface of the optical patch panel 22, there are number labels 26 on which adapter identification numbers 1 to 12, 13 to 24, 25 to 36, and 37 to 48 are written along the respective row directions of the optical connector adapter 23. It is pasted.

  FIG. 5A is a plan view of the adapter identification jig 31 of the present embodiment, and FIG. 5B is a side view thereof.

  In this embodiment, the adapter identifying jig 31 is made of a rectangular aluminum plate having a length of 140 mm, a width of 45 mm, and a thickness of 0.5 mm. The thickness of the adapter identification jig 31 is designed to be such that the adapter identification jig 31 is firmly sandwiched between the connector adapters 23 according to the height dimension of the opening into which the optical connector adapter 23 is fitted. A number label 32 is affixed to the plate surface of the adapter identification jig 31. On the number label 32, the identification number of the optical connector adapter 23 is written corresponding to the stacking position of the optical connector adapter 23. On the plate surface of the adapter identification jig 31, the identification number of the optical connector adapter 23 is optical. It is shown corresponding to the stacking position of the connector adapter 23.

  The adapter identification jig 31 is inserted across the rows as shown in FIG. 6 in the gaps between the optional optical connector adapters 23 stacked as shown in FIG. 4 and divides each row. 6 that are the same as or correspond to those in FIG. 4 are assigned the same reference numerals, and descriptions thereof are omitted. And the adapter identification jig | tool 31 is made to identify so that the positional relationship of each optical connector adapter 23 arranged along the plate | board surface of the part | segmented location may be mentioned later. As shown in FIG. 5, the adapter identification jig 31 is formed with an elongated hole-shaped window 33. 7 is a partial perspective view of the panel surface of the optical patch panel 22 that is hidden by the plate surface of the adapter identification jig 31 when the adapter identification jig 31 is inserted over each row and divided. Come as shown. 7 that are the same as or correspond to those in FIG. 5 and FIG. A round hole 34 is formed on the right shoulder of the adapter identification jig 31. The round hole 34 is used when the adapter identification jig 31 is hooked on a hook or the like and stored, or when the adapter identification jig 31 is suspended from the operator's neck through a string.

  According to the present embodiment, as described above, the single optical connector adapter 23 is fitted with play in the row direction in the openings formed in the optical patch panel 22 in four rows. 4 are stacked in four rows as shown in FIG. Accordingly, each optical connector adapter 23 is moved in the row direction in each laminated opening, and a plate-shaped adapter identification jig 31 as shown in FIG. 6 can be inserted across each row. For this reason, as in the present embodiment, the rows of the optical connector adapters 23 are sequentially arranged in the depth direction from the front of the optical connection box 11, and the insertion / extraction direction of the optical connector plug 25 is the width direction of the optical connection box 11. If there are a lot of optical connector adapters 23 and optical fiber cords 24 provided on the optical patch panel 22, the adapter identification numbers 1 to 12 on the front side of the optical connection box 11 can be easily visually confirmed. A longitudinal end on the front side of the plate-shaped adapter identification jig 31 is pushed between any optical connector adapters 23, and in this state, the longitudinal end on the back side of the adapter identification jig 31 is connected to the back row. By pushing in between the optical connector adapters 23, the adapter identification jig 31 can be inserted between the stacked arbitrary optical connector adapters 23 across the respective rows to divide each row. .

  The optical connector adapters 23 in the back row can be identified by identifying the positional relationship between the optical connector adapters 23 arranged along the plate surface of the adapter identification jig 31 at the divided location. . That is, among the optical connector adapters 23 arranged along the plate surface of the adapter identification jig 31 at the divided position, the optical connector adapter 23 on the near side can easily visually check the adapter identification numbers 1 to 12 thereof. Therefore, if the adapter identification number of the optical connector adapter 23 in the corresponding row is confirmed in advance, the adapter identification number can be grasped based on the relationship between the optical connector adapters 23 arranged in each column. From the relationship with the optical connector adapter 23 on the side, the optical connector adapter 23 in the back row can be identified. For example, as shown in FIG. 6, when the front end in the longitudinal direction of the adapter identification jig 31 is pushed between the optical connector adapters 23 in the foremost row with adapter identification numbers 8 and 9, they are arranged in each row. Adapter identification of the second row of optical connector adapters 23 arranged in the row direction along the plate surface of the adapter identification jig 31 at the divided location based on the previously recognized relationship between the optical connector adapters 23 being The number can be identified as 20, the adapter identification number of the optical connector adapter 23 in the third row is 32, and the adapter identification number of the optical connector adapter 23 in the fourth row can be identified as 44.

  Therefore, even when the row of optical connector adapters 23 is arranged in the depth direction from the front of the optical connection box 11 and there are many optical connector adapters 23 and optical fiber cords 24 provided on the optical patch panel 22, the optical connector adapters 23 are targeted for insertion / extraction. It becomes possible to specify the optical connector adapter 23 easily and reliably. For example, in the above example, in order to specify the optical connector adapter 23 with the adapter identification number 44, the adapter identification jig 31 is inserted between the optical connector adapters 23 in the forefront row with the adapter identification number 8 and 9. Thus, it is possible to specify that the optical connector adapters in the fourth row arranged along the plate surface of the adapter identification jig 31 at the divided location correspond.

  In addition, since the lower optical connector adapter 23 group and the optical fiber cord 24 group divided by the adapter identification jig 31 are hidden behind the adapter identification jig 31 and cannot be touched, the optical connector plug that is not a work target when the optical connector plug 25 is inserted or removed. The possibility of erroneously grasping the optical connector plug 25 is reduced, and the optical connector adapter 23 group and the optical fiber cord 24 group that are not work targets are not obstructed by the optical connector plug 25 insertion / extraction operation. As a result, the workability of the insertion / extraction work of the optical connector plug 25 is improved. In addition, since each optical connector adapter 23 can be identified even when a large number of optical connector adapters 23 are arranged, the optical patch panel 22 and thus the optical connection box 11 can be made smaller. In addition, since the adapter identification jig 31 is simply constituted by a plate-like member, the cost for manufacturing the adapter identification jig 31 is reduced.

  Further, according to the present embodiment, the panel surface of the optical patch panel 22 that is inserted over each row and is hidden by the plate surface of the adapter identification jig 31 when the row is divided is shown in FIG. It is visually recognized from the window 33 formed in the identification jig 31. For this reason, in addition to the positional relationship between the optical connector adapters 23 arranged along the plate surface of the adapter identification jig 31 at the divided location, the panel surface of the optical patch panel 22 viewed from the window 33 of the adapter identification jig 31 The positional relationship with the optical connector adapter 23 attached to is also grasped. For example, in the above example, in addition to the positional relationship that the adapter identification numbers of the optical connector adapters 23 arranged along the plate surface of the adapter identification jig 31 at the divided location are 8, 20, 32, 44, the adapter From the positional relationship that the adapter identification number of the optical connector adapter 23 that is visually recognized from the window 33 of the identification jig 31 and is below the optical connector adapter 23 in the second row divided by the adapter identification jig 31 is 21. It is understood that the adapter identification number of the optical connector adapter 23 in the second row divided by the adapter identification jig 31 is 20. For this reason, according to this Embodiment in which the window 33 was formed in the adapter identification jig | tool 31, identification of the optical connector adapter 23 made into work object can be performed more easily.

  Further, according to the present embodiment, for example, the adapter identification numbers 20, 32, and 44 in the back row are determined from the relationship with the optical connector adapter 23 of the adapter identification number 8 on the near side where the adapter identification number can be grasped. When identifying the optical connector adapter 23, it is easy to refer to the number label 32 attached to the adapter identification jig 31 based on the relationship between the optical connector adapters 23 arranged in each row. The optical connector adapter 23 in the back row can be identified. That is, by referring to, for example, the display “8 20 32 44” of the row of the adapter identification number 8 shown in the number label 32 as shown in FIG. 5 corresponding to the stacking position of the optical connector adapter 23, it is easy. It is possible to specify that the adapter identification numbers of the optical connector adapters 23 arranged along the plate surface of the adapter identification jig 31 on the back side of the optical connector adapter 23 having the adapter identification number 8 are 20, 32, and 44.

  Moreover, according to this Embodiment, the adapter identification jig | tool 31 which can identify the optical connector adapter 23 in the optical patch panel 22 in the optical connection box 11 easily and reliably is provided.

  In the present embodiment, the case where the adapter identification jig 31 is formed from an aluminum plate has been described. However, the material is not limited to this, and the adapter identification jig 31 may be formed from a resin plate, for example. When formed with a resin plate, the optical connector adapter 23 can be prevented from being damaged when the adapter identification jig 31 is inserted between the optical connector adapters 23. In addition, the correspondence table of the adapter identification numbers indicating the arrangement of the optical connector adapters 23 attached to the back side from the front row is described on the number label 32 and configured to be affixed to the adapter identification jig 31. A correspondence table of adapter identification numbers may be directly written on the plate surface of the tool 31 by printing or engraving.

  In the above embodiment, the adapter identifying jig 31 according to the present invention is used for identifying the optical connector adapter 23 in the optical patch panel 22 in the optical connection box 11, but the present invention is not limited to this, The present invention can be applied to all products including the optical patch panel 22 to which the optical connector adapter 23 is attached. Even in that case, the same effects as those of the above-described embodiment can be obtained.

DESCRIPTION OF SYMBOLS 11 ... Optical connection box 11a ... Body 11b ... Cover 11c ... Opening part 12 ... Base board 13 ... Fusion splicing unit 14 ... Connector connection unit 15, 16 ... Pull-out table 15a, 16a ... Pulling part 17 ... External fiber cable DESCRIPTION OF SYMBOLS 18 ... 4-core tape core wire 19 ... 4-fiber FO cord 20, 25 ... Optical connector plug 21 ... Cord tray 22 ... Optical patch panel 23 ... Optical connector adapter 24 ... On-site optical fiber cord 26, 32 ... Number label 31 ... Adapter identification Jig 33 ... Window 34 ... Round hole

Claims (4)

An adapter identification jig for identifying single-core optical connector adapters that are fitted with play in the row direction in the openings formed in a plurality of rows on the optical patch panel and stacked in a plurality of rows,
The positions of the optical connector adapters that are plate-shaped and that are inserted between the stacked optical connector adapters across the rows to divide the rows and that are lined up along the plate surfaces of the divided locations. Adapter identification jig characterized by identifying relationships.   The adapter identification jig according to claim 1, wherein a window is formed to face the panel surface of the optical patch panel that is inserted over each of the rows and is hidden by a plate surface when the rows are divided. .   The adapter identification jig according to claim 1 or 2, wherein an identification number of the optical connector adapter is represented on a plate surface corresponding to a stacking position of the optical connector adapter.   The adapter identification according to any one of claims 1 to 3, wherein the optical patch panel is configured to connect optical connector plugs to each other via the optical connector adapter in an optical connection box. jig.

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