CN212463217U - Optical fiber jumper wire receiving and transmitting optical detection device - Google Patents

Abstract

The utility model provides an optical fiber jumper wire receiving and dispatching optical detection device can be used to finance field or other fields, and the device includes: the first detection piece is provided with a first optical fiber connector jack and a first pore passage, a first light sensing element is arranged in the first detection piece, and the first light sensing element is connected with one end of a first optical fiber jumper wire through the first optical fiber connector jack; one end of the first hole is connected with the first light sensing element, so that light emitted by the first light sensing element when the first optical fiber jumper receives light is emitted from the first hole to indicate the light receiving and transmitting state of the first optical fiber jumper. The optical fiber jumper wire receiving and sending light detection device is simple and reliable in structure and capable of efficiently identifying the receiving and sending light states of the optical fiber jumper wires.

Description

Optical fiber jumper wire receiving and transmitting optical detection device

Technical Field

The utility model relates to an optical fiber jumper technical field, concretely relates to optical fiber jumper wire send-receiver light detection device.

Background

The optical fiber jumper, also called optical fiber connector, has connectors at both ends (common optical fiber connectors are large square-head connectors, i.e. SC-type connectors, small square-head connectors, i.e. LC-type connectors, round-head connectors, i.e. FC-type connectors, and clamping-type round connectors, i.e. ST-type connectors), and is mainly used for optical fiber connection among optical fiber distribution frames, optical fiber transceivers or equipment. The optical fiber patch cord generally appears in pairs, namely light receiving and light emitting, and has the characteristics of high transmission speed, long distance, large bandwidth, strong anti-interference performance and the like, so that the optical fiber patch cord is widely applied to the fields of intelligent weak current industry and network engineering.

In daily use practice, constructors often encounter a problem, after the optical fiber patch cord is connected, the circuits are not communicated because the optical fiber ports of the two-end equipment receive and emit light inconsistently, therefore, the optical fiber patch cord needs to be checked again and distinguished to receive and emit light, and then optical fiber connectors need to be changed again, and only the optical fibers received and emitted by the two-end equipment ports are matched, interconnection and intercommunication can be realized, so that engineering implementation personnel need to perform troubleshooting due to the problem, certain labor cost is wasted, and project engineering progress is directly influenced.

SUMMERY OF THE UTILITY MODEL

To the problem among the prior art, the utility model provides an optical fiber jumper wire receiving and dispatching light detection device, optical fiber jumper wire receiving and dispatching light detection device simple structure and reliable can the high-efficient receiving and dispatching light state of discerning the optical fiber jumper wire.

In order to solve the technical problem, the utility model provides a following technical scheme:

the application provides an optical fiber jumper wire receiving and dispatching optical detection device, includes:

the first detection piece is provided with a first optical fiber connector jack and a first pore passage, a first light sensing element is arranged in the first detection piece, and the first light sensing element is connected with one end of a first optical fiber jumper wire through the first optical fiber connector jack;

one end of the first hole is connected with the first light sensing element, so that light emitted by the first light sensing element when the first optical fiber jumper receives light is emitted from the first hole to indicate the light receiving and transmitting state of the first optical fiber jumper.

Further, the optical fiber jumper wire transceiving and detecting device further comprises: the second detection piece is provided with a second optical fiber connector jack and a second pore passage, a second light sensing element is arranged in the second detection piece, the second light sensing element is connected with one end of a second optical fiber jumper wire through the second optical fiber connector jack, and the other ends of the first optical fiber jumper wire and the second optical fiber jumper wire are connected with the same equipment; one end of the second hole is connected with the second light sensing element, so that light emitted by the second light sensing element when the second optical fiber jumper receives light is emitted from the second hole to indicate the light receiving and transmitting state of the second optical fiber jumper.

Further, a fixing part is arranged between the first detection part and the second detection part, so that the relative position between the first detection part and the second detection part is stable.

Further, the optical fiber jumper wire transceiving and detecting device further comprises: and the protective cap is detachably connected with the first optical fiber connector jack and used for protecting the first optical fiber connector jack.

Furthermore, the first optical fiber connector jack is clamped with an optical fiber jumper connector of the first optical fiber jumper.

Furthermore, the first optical fiber connector jack is connected with the optical fiber jumper connector of the first optical fiber jumper in a plug-and-pull latch manner.

Further, the optical fiber jumper wire transceiving and detecting device further comprises: and the window body is clamped with one end of the first detection part and completely shields the first pore channel and is used for protecting the first pore channel and the first light sensing element.

Further, the outer wall of the first detection piece is provided with an insulating layer.

Further, the outer wall of the first detection piece is provided with a flame-retardant coating.

Further, the first detecting member is a cylindrical structure.

According to the above technical scheme, the utility model provides an optical fiber jumper wire receiving and dispatching light detection device, include: the first detection piece is provided with a first optical fiber connector jack and a first pore passage, a first light sensing element is arranged in the first detection piece, and the first light sensing element is connected with one end of a first optical fiber jumper wire through the first optical fiber connector jack; one end of the first hole is connected with the first light sensing element, so that light rays emitted by the first light sensing element when the first optical fiber jumper receives light are emitted from the first hole to indicate the light receiving and transmitting state of the first optical fiber jumper; the structure is simple and reliable, and the receiving and transmitting optical states of the optical fiber patch cord can be efficiently identified; the operation is simple, and a user can simply and visually identify and judge whether the optical fiber jumper is luminous or not through naked eyes, so that whether equipment circuits at two ends are conducted or not can be efficiently and accurately determined; meanwhile, the jumper wire connector can play the safety protection roles of dust prevention, folding prevention, loss prevention and the like, is low in manufacturing cost, does not need extra power connection, can be repeatedly used, and has high practical value and commercial potential.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the application.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic diagram illustrating a connection relationship between an optical fiber patch cord transceiving optical detection device and an optical fiber patch cord in an embodiment of the present application.

Fig. 2 is a schematic view of a first structure of the optical fiber jumper transceiving detection device in the embodiment of the present application.

Fig. 3 is a schematic diagram of a second structure of the optical fiber jumper transceiving detection device in the embodiment of the present application.

Fig. 4 is a logic diagram between the optical fiber jumper wire transceiving optical detection device and the optical fiber jumper wire in the embodiment of the present application.

Reference numerals:

1. a first duct;

2. a first detecting member;

3. a fixing member;

4. a first optical fiber jumper;

5. a first optical fiber jumper connector;

6. a first light sensing element;

7. a first fiber optic splice receptacle;

8. a first optical cable;

9. a second duct;

10. a second detecting member;

11. and a second optical fiber jumper.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Specific embodiments of the present invention are disclosed in detail with reference to the following description and the accompanying drawings, which specify the manner in which the principles of the invention may be employed. It should be understood that the embodiments of the present invention are not so limited in scope. The embodiments of the invention include many variations, modifications and equivalents within the spirit and scope of the appended claims.

Features that are described and/or illustrated with respect to one embodiment may be used in the same way or in a similar way in one or more other embodiments, in combination with or instead of the features of the other embodiments.

It should be emphasized that the term "comprises/comprising" when used herein, is taken to specify the presence of stated features, integers, steps or components but does not preclude the presence or addition of one or more other features, integers, steps or components.

It should be noted that the optical fiber jumper wire transceiving optical detection device disclosed in the present application may be used in the field of financial technology, and may also be used in any field other than the field of financial technology.

The utility model provides an example of optic fibre wire jumper receiving and dispatching light detection device, simple structure and reliable, the receiving and dispatching light state that can high-efficient discernment optic fibre wire jumper, see figure 1 and figure 2, this optic fibre wire jumper receiving and dispatching light detection device includes:

the optical fiber patch panel comprises a first detection piece 2, wherein the first detection piece 2 is provided with a first optical fiber connector jack 7 and a first duct 1, a first optical sensing element 6 is arranged in the first detection piece, and the first optical sensing element 6 is connected with one end of a first optical fiber patch cord 4 through the first optical fiber connector jack 7; one end of the first hole is connected with the first light sensing element, so that light emitted by the first light sensing element 6 when the first optical fiber jumper 4 receives light is emitted from the first hole 1, and the light receiving and sending states of the first optical fiber jumper 4 are indicated.

Specifically, the first detection piece is used for protecting the first light sensing element and the first optical fiber jumper, and the first light sensing element is arranged in the first detection piece; the first detection piece can be of a cylindrical structure, so that the size of the first optical fiber jumper wire transceiving detection device can be saved; the outer wall of the first detection piece can be provided with an insulating layer, the outer wall of the first detection piece can be provided with a flame-retardant coating, the inner walls of the first optical fiber connector jack and the first hole channel can also be provided with an insulating layer and a flame-retardant layer, so that the first optical fiber jumper wire and the first light sensing element can be further protected, and the safety of the optical fiber jumper wire receiving and sending optical detection device is improved. The first detection piece can be of a cylindrical structure made of insulating materials such as rubber or plastics, and materials of the first detection piece can be saved. The optical fiber jumper receiving and transmitting states comprise: the optical fiber jumper wire receives light and emits light.

Further, the first optical fiber jumper transceiving optical detection device further includes: and the protective cap is detachably connected with the first optical fiber connector jack and used for protecting the first optical fiber connector jack. The first light sensing element can be a light sensing element provided with a light emitting source and can emit light.

Further, referring to fig. 4, the first optical fiber connector jack 7 is clamped with the optical fiber jumper connector 5 of the first optical fiber jumper. When the first optical fiber jumper receives light, the light emitted by the first light sensing element 6 is emitted from the first hole 1; when the first optical fiber jumper emits light, the first light sensing element does not emit light. The first optical fiber jumper includes: a first optical cable 8 and an optical fibre jumper connection 5 connected to the first optical cable. The first optical fiber connector jack and the optical fiber jumper connector of the first optical fiber jumper can be connected in a plug-and-pull latch mode. The plug-in bolt type fastening mode is adopted, rotation is not needed, the plug-in operation is convenient, and the insertion loss fluctuation is small. The optical fiber jumper connector is one of a large square head connector, a small square head connector, a round rotary head connector and a clamping type round connector.

Further, the first optical fiber jumper transceiving optical detection device further includes: and the window body is clamped with one end of the first detection part and completely shields the first pore channel and is used for protecting the first pore channel and the first light sensing element. The window may be a double-layer transparent glass window or a transparent plastic window, and can protect the first duct and the first light-sensing element.

As can be seen from the above description, the optical fiber patch cord transceiving optical detection device provided by the embodiment has a simple and reliable structure, and can efficiently identify the transceiving optical state of the optical fiber patch cord; particularly, in the construction process, the receiving and sending optical states of the current optical fiber patch cord can be confirmed in time, and the circuit abnormity caused by the same receiving and sending optical states when other optical fiber patch cords are deployed next is avoided.

In an embodiment of the present invention, referring to fig. 1, the optical fiber jumper wire transceiving optical detection device further includes: the second detection piece 10 is provided with a second optical fiber connector jack and a second duct 9, a second light sensing element is arranged in the second detection piece 10, the second light sensing element is connected with one end of a second optical fiber jumper 11 through the second optical fiber connector jack, and the other ends of the first optical fiber jumper and the second optical fiber jumper are connected with the same equipment; one end of the second hole is connected with the second light sensing element, so that light emitted by the second light sensing element when the second optical fiber patch cord receives light is emitted from the second hole to indicate the light receiving and transmitting state of the second optical fiber patch cord 11. Specifically, the other end of the first optical fiber jumper and the other end of the second optical fiber jumper are connected with the same device.

Further, referring to fig. 1 and 3, a fixing member 3 is disposed between the first detecting member 2 and the second detecting member 10 to stabilize a relative position between the two first detecting members 2 and the second detecting member. The fixing piece can be a cylindrical structure made of insulating materials, one or more fixing pieces can be arranged between the first detection piece 2 and the second detection piece, and the stability between the first detection piece and the second detection piece can be improved. The optical fiber jumper wire transceiving optical detection device may further include: the other protective cap is detachably connected with the second optical fiber connector jack; the method can also comprise the following steps: the other window body is clamped with one end of the second detection piece and completely shields the second pore channel and is used for protecting the second pore channel and the second light sensing element; the second optical fiber connector jack can be clamped with an optical fiber jumper connector of a second optical fiber jumper. The first and second detecting members may be identical.

In the first optical fiber jumper and the second optical fiber jumper, when one optical fiber jumper receives light and the other optical fiber jumper emits light, the optical fiber jumpers are correctly connected, and equipment circuits at two ends are conducted; otherwise, the optical fiber jumper is wrongly connected, and the equipment lines at the two ends are not conducted. According to the optical fiber jumper wire receiving and transmitting detection device provided by the embodiment, the receiving and transmitting optical states of the first optical fiber jumper wire and the second optical fiber jumper wire can be visually identified, and the reliability of optical fiber jumper wire protection can be further improved.

Based on the above, the present application further provides an application example of the optical fiber jumper transceiving optical detection device, where the internal structure of the device includes:

1. the optical fiber connector jack is used for connecting an optical fiber jumper connector, adopts a plug pin bolt type fastening mode, does not need to rotate, is convenient to plug and pull, and has small insertion loss fluctuation. When the optical fiber connector jack is not connected with the optical fiber jumper connector, the protective cap can be configured, and the jack is ensured to be dust-free. The corresponding type customization can be carried out according to different optical fiber jumper wire connectors (such as a large square head connector, namely an SC type connector, a small square head connector, namely an LC type connector, a round head connector, namely an FC type connector, a clamping type round connector, namely an ST type connector and the like).

2. And the light sensing element is arranged in the optical fiber jumper wire transceiving and detecting device, and the light sensing element can shine after receiving light and is butted with the optical fiber connector jack.

3. The light sensing display hole, namely the pore passage, is butted with the light sensing element, and whether the light sensing element shines or not can be judged by naked eyes through the light sensing display hole.

After the optical fiber jumper wire joint is connected with the optical fiber jumper wire transceiving and detecting device, when the optical fiber jumper wire is lighted; the optical fiber connector jack receives light through the optical fiber jumper connector; the light sensing element can emit light after receiving the light; the light source is displayed through the light sensation display hole, and personnel can visually identify the light emitting state of the light sensation display hole.

The optical fiber jumper wire receiving and sending light detection device is connected with the optical fiber connector at one end of the optical fiber jumper wire, when the optical fiber jumper wire is lighted after equipment connected with the other end of the optical fiber jumper wire is started, the optical fiber jumper wire receiving and sending light detection device can receive light, wherein the corresponding optical fiber jumper wire receiving light connector side enables the light sensation display hole to be lighted, the corresponding jumper wire emitting light connector side enables the light sensation display hole to be not lighted, namely the light sensation display hole is "lighted" to be used as the light receiving light connector, and the light sensation display hole is "unlighted" to be used as the. And then can rely on the naked eye to judge that the optic fibre wire jumper receives light or shines simply, directly perceivedly, then correspondingly with optic fibre wire jumper connection equipment, can guarantee the optical connection exactness between the equipment.

The present invention has been explained by using specific embodiments, and the explanation of the above embodiments is only used to help understand the method and the core idea of the present invention; meanwhile, for the general technical personnel in the field, according to the idea of the present invention, there are changes in the specific implementation and application scope, to sum up, the content of the present specification should not be understood as the limitation of the present invention.

Claims (10)

1. An optical fiber jumper wire transceiving optical detection device, comprising:

the first detection piece is provided with a first optical fiber connector jack and a first pore passage, a first light sensing element is arranged in the first detection piece, and the first light sensing element is connected with one end of a first optical fiber jumper wire through the first optical fiber connector jack;

one end of the first hole is connected with the first light sensing element, so that light emitted by the first light sensing element when the first optical fiber jumper receives light is emitted from the first hole to indicate the light receiving and transmitting state of the first optical fiber jumper.

2. The optical fiber jumper transceiver photodetection device according to claim 1, characterized by further comprising:

the second detection piece is provided with a second optical fiber connector jack and a second pore passage, a second light sensing element is arranged in the second detection piece, the second light sensing element is connected with one end of a second optical fiber jumper wire through the second optical fiber connector jack, and the other ends of the first optical fiber jumper wire and the second optical fiber jumper wire are connected with the same equipment;

one end of the second hole is connected with the second light sensing element, so that light emitted by the second light sensing element when the second optical fiber jumper receives light is emitted from the second hole to indicate the light receiving and transmitting state of the second optical fiber jumper.

3. The optical fiber jumper transreceiving and detecting device according to claim 2, wherein a fixing member is provided between the first detecting member and the second detecting member to stabilize a relative position between the first detecting member and the second detecting member.

4. The optical fiber jumper transceiver photodetection device according to claim 1, characterized by further comprising:

and the protective cap is detachably connected with the first optical fiber connector jack and used for protecting the first optical fiber connector jack.

5. The optical fiber jumper wire transceiving optical detection device of claim 1, wherein the first optical fiber connector jack is snap-fitted to an optical fiber jumper connector of the first optical fiber jumper wire.

6. The optical fiber jumper transreceiving detection device of claim 1, wherein the first optical fiber splice receptacle is in a bayonet-latch connection with an optical fiber jumper splice of the first optical fiber jumper.

7. The optical fiber jumper transceiver photodetection device according to claim 1, characterized by further comprising: and the window body is clamped with one end of the first detection part and completely shields the first pore channel and is used for protecting the first pore channel and the first light sensing element.

8. The optical fiber jumper transreceiving and detecting device according to claim 1, wherein an outer wall of the first detecting member is provided with an insulating layer.

9. The optical fiber jumper transreceiving and photodetecting device according to claim 1, characterized in that the outer wall of the first detecting member is provided with a flame retardant coating.

10. The optical fiber jumper transceiver detection device of claim 1, wherein the first detection member is a cylindrical structure.

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