CN118129913A - Portable optical fiber color recognition assembly equipment and system - Google Patents

Abstract

The application relates to the technical field of image recognition, and provides portable optical fiber color recognition assembly equipment and system. The portable optical fiber color recognition assembly device includes: the box body is internally provided with a first accommodating part; a movable platform disposed in the first accommodation portion; the light source is arranged in the box body, and the irradiation direction of the light source faces the movable platform; the first through hole is formed in the box body; the first through hole is opposite to the background plate, so that the camera device of the mobile terminal can recognize the color of the optical fiber through the first through hole. The portable optical fiber color recognition assembly equipment can provide a stable recognition environment for optical fiber color recognition under an open environment, and improves recognition accuracy. In addition, the optical fiber placing operation is simplified, the working efficiency is improved, and the mobile terminal placing device has high convenience.

Description

Portable optical fiber color recognition assembly equipment and system

Technical Field

The application relates to the technical field of image recognition, in particular to portable optical fiber color recognition assembly equipment and system.

Background

With the development of communication technology, the transmission speed of an optical fiber communication system is continuously increasing. Modern optical fiber communication systems can realize high-speed data transmission and meet the requirements of various applications.

In different usage scenarios, the working modes of the optical fibers are different, and the working modes of the optical fibers can be distinguished by the colors of the optical fibers. Therefore, when the optical fiber is paved, the working mode of the optical fiber is determined according to the requirement of a use scene, and then the color of the corresponding optical fiber is determined according to the working mode of the optical fiber. For example, the transmission distance is different and the color of the optical fiber used is different. Wherein, yellow may represent a single mode fiber, which may be used for telecommunications. Orange may represent a multimode optical fiber that may be used for short-range data transmission. In this way, during the process of laying the optical fiber, a more suitable optical fiber can be selected according to the requirements of the use scene.

Some optical fiber color recognition devices adopt image recognition technology, and can recognize the color, texture, shape and the like of an optical fiber in a standard environment. However, these optical fiber color recognition devices are more demanding in terms of the use environment. For example, if the optical fiber color recognition device is used in a closed environment which is not interfered by the factors such as ambient light and weather, the recognition accuracy of the optical fiber color recognition device is reduced if the optical fiber color recognition device is used in an open environment.

Disclosure of Invention

The application provides portable optical fiber color recognition assembly equipment and a system, which aim to solve the technical problem of low recognition accuracy caused by the influence of recognition environments in the conventional optical fiber color recognition equipment.

The portable optical fiber color recognition assembly device provided in the first aspect of the present application comprises: the box body is internally provided with a first accommodating part; a movable platform disposed in the first accommodation portion; the movable platform comprises a background plate, wherein the background plate is used for placing optical fibers; the light source is arranged in the box body, and the irradiation direction of the light source faces the movable platform; the first through hole is formed in the box body; wherein, one side of the box body, which is away from the first accommodating part, is used for installing a mobile terminal for identifying the color of the optical fiber; the first through hole is opposite to the background plate, so that the camera device of the mobile terminal can recognize the color of the optical fiber through the first through hole.

In some possible implementations, the movable platform includes: the sliding groove is formed in the inner wall of the box body; the installation component is slidably arranged on the chute and is used for installing the optical fiber; a handle connected to the mounting assembly; wherein, the box body includes the breach, and the handle sets up at the breach with sliding out.

In some possible implementations, the handle is provided with a first groove extending in the height direction of the handle; the box body is equipped with the second recess, and the second recess is along the direction of wearing to establish of optic fibre, sets up the opposite end at the breach, and wherein, first recess and second recess are used for wearing to establish optic fibre.

In some possible implementations, the mounting assembly includes: the mounting plate is slidably arranged on the chute, and one end of the mounting plate is connected with the handle; the two clamping blocks are arranged on the mounting plate and are respectively positioned at two sides of the background plate; the clamping block is used for fixing the optical fiber; the backup pad sets up on the mounting panel, and the backup pad is close to the setting of second recess, and wherein, the backup pad is used for supporting optic fibre.

In some possible implementations, the clamp block includes: the clamping block body is arranged on the mounting plate; wherein, the surface of the clamp splice body is provided with a mounting groove which is used for mounting the optical fiber; the pressing plate is rotatably buckled on the clamping block body; the foam is arranged on the pressing plate and is opposite to the mounting groove, wherein when the pressing plate is buckled, the foam is configured to cover the mounting groove; the magnet is arranged on the surface of the clamp block body and is arranged at intervals with the mounting groove, and the magnet is used for magnetically attracting the pressing plate, wherein when the pressing plate is buckled, the foam is further arranged at intervals with the magnet.

In some possible implementations, the bottoms of the first groove and the second groove are provided with chamfers.

In some possible implementations, the mounting plate is coupled to the handle screw.

In some possible implementations, the background plate is white.

In some possible implementations, the case includes a case cover and a case body: the box cover is rotatably arranged on the box body and is used for installing the mobile terminal; the box body is internally provided with a first accommodating part, and the notch is formed in the box body.

In some possible implementations, the lid includes: a box cover body; the accommodating groove is formed in the box cover body, the opening of the accommodating groove faces the background plate, the first through hole is formed in the central area of the accommodating groove, and the light source is arranged in the accommodating groove; the light homogenizing plate is covered on the light source and is provided with a second through hole; the light guide plate is fixed on the box cover body, and the cover is arranged on the light homogenizing plate, and the light guide plate is provided with a third through hole, wherein the position and the area of the first through hole, the second through hole and the third through hole are the same.

In some possible implementations, the light source includes a plurality of LED light beads.

In some possible implementations, the light guide plate is screwed with the cover body.

In some possible implementations, the accommodating groove is a square groove, and the light homogenizing plate and the light guide plate are square.

In some possible implementations, the box cover further includes a magnetic attraction portion disposed in a central area of the box cover body, and the magnetic attraction portion is used for magnetically attracting the mobile terminal.

In some possible implementations, the lid further includes: the first sliding block and the second sliding block are arranged on the surface of one side, away from the box body, of the box cover body, and the first sliding block and the second sliding block are arranged at two ends of the box cover body along the length direction of the box cover body; wherein the first slider and the second slider are used for fixing two ends of the mobile terminal.

In some possible implementations, the lid further includes: the baffle structure is arranged at the top of the outer surface of the box cover body, the section of the baffle structure is U-shaped, and the opening of the U-shape faces the bottom of the outer surface of the box cover body; the first sliding block is arranged in the U-shaped opening; the two first bosses are arranged along the width direction of the box cover body, each first boss extends along the length direction of the box cover body, and the first sliding block is slidably arranged on the first bosses; the first sliding block moves along the length direction of the first boss relative to the box cover body so as to adjust the top position of the mobile terminal.

In some possible implementations, the lid further includes: the guide piece is arranged between the top of the inner wall of the baffle plate structure and the first sliding block, and extends along the length direction of the box cover body; and the limiting piece is arranged between the side wall of the inner wall of the baffle structure and the first sliding block, and extends along the width direction of the box cover body.

In some possible implementations, the lid further includes: the second sliding blocks are arranged on the second bosses in a sliding manner, wherein the two second bosses are arranged along the width direction of the box cover body, each second boss extends along the length direction of the box cover body, and the second sliding blocks move along the length direction of the second bosses relative to the box cover body so as to adjust the bottom position of the mobile terminal; the fixing piece is arranged between the box cover body and the second sliding block, and when the fixing piece is configured to be in a fastening state, the second sliding block and the box cover body are limited to generate relative displacement.

In some possible implementations, the portable fiber optic color identification assembly device further includes: the pressing block is arranged on the box cover; the micro switch is arranged on the box body, and the pressing block is opposite to the micro switch in position; when the box cover is buckled, the pressing block is configured to toggle the micro switch; the micro switch is configured to turn on the light source when being stirred by the pressing block; the box body also comprises a second accommodating part, and the first accommodating part and the second accommodating part are separated by a partition plate; the portable optical fiber color recognition assembly device further includes: the power supply module is arranged at the second accommodating part and is used for providing electric energy for the light source.

In some possible implementations, the portable fiber optic color identification assembly device further includes: the cooperation piece, set up the lateral wall at the lid, and the cooperation piece is close to the rotation junction of lid and box body, and the sloping block sets up the lateral wall at the box body, and cooperation piece is relative with sloping block position, and wherein, when the lid was opened to limit state, the cooperation piece was configured to laminating on the sloping of sloping block.

In some possible implementations, the mating block is a cube or cuboid, and the inclined surface of the inclined block is inclined at 45 °.

In some possible implementations, the portable fiber optic color identification assembly device further includes: the control switch is arranged on the side wall of the box body and used for controlling the state of the power supply module; the indicator lamp is arranged on the side wall of the box body and is close to the control switch and used for displaying the working state of the power supply module.

The portable optical fiber color recognition assembly equipment provided by the first aspect of the application can provide a closed condition for optical fiber color recognition, is not influenced by external environment, provides a stable recognition environment for optical fiber color recognition under the conditions that the color of the optical fiber is difficult to recognize in a submarine cable mass production stage, submarine cable construction and delivery site and relatively complex environment, and improves recognition accuracy. In addition, the simple and convenient optical fiber placement operation improves the working efficiency for users, provides various possibilities for an optical fiber identification scheme, and has higher convenience.

A second aspect of the present application provides a portable optical fiber color identification system, comprising: the portable optical fiber color recognition assembly device provided in the first aspect; and the mobile terminal is arranged on the box body and is used for identifying the color of the optical fiber.

The portable optical fiber color recognition system provided in the second aspect of the present application includes the portable optical fiber color recognition assembly device provided in the first aspect, so that the beneficial technical effects of the second aspect can be referred to in the first aspect, and are not repeated herein.

Drawings

In order to more clearly illustrate the technical solution of the present application, the drawings that are needed in the embodiments will be briefly described below, and it will be obvious to those skilled in the art that other drawings can be obtained from these drawings without inventive effort.

Fig. 1 is a schematic perspective view of a portable optical fiber color recognition assembly device according to an embodiment of the present application;

FIG. 2 is a schematic structural diagram of a portable optical fiber color recognition assembly device according to an embodiment of the present application;

FIG. 3 is a schematic diagram of another portable optical fiber color recognition assembly device according to an embodiment of the present application;

FIG. 4 is a schematic diagram of a movable platform according to an embodiment of the present application;

FIG. 5 is an exploded view of a mobile platform according to an embodiment of the present application;

FIG. 6 is an exploded view of a lid according to an embodiment of the present application;

FIG. 7 is an exploded view of another lid provided in accordance with an embodiment of the present application;

FIG. 8 is a schematic perspective view of another portable optical fiber color recognition assembly device according to an embodiment of the present application;

FIG. 9 is a schematic diagram showing a comparison between an unapplied state and an attached state of the engaging block and the inclined block according to the embodiment of the present application;

Fig. 10 is a block diagram of a portable optical fiber color recognition system according to an embodiment of the present application.

The graphic indicia:

100-portable optical fiber color recognition assembly equipment; 10-a box body; 101-a first receptacle; 102-a first via; 103-notch; 104-a second groove; 105-lid; 1051-a lid body; 1052-receiving slot; 1053-light homogenizing plate; 1053 a-second via; 1054-light guide plate; 1054 a-third via; 1055-magnetic attraction portion; 1056-first slider; 1056 a-kidney aperture; 1057-a second slider; 1058-baffle structure; 1059-first boss; 1060-a guide; 1061—a stop; 1062-a second boss; 1063-securing member; 1064-briquetting; 1065-a second receptacle; 1066-separator; 1067-mating blocks; 1068-recesses; 1069-cover plate; 105 a-a first magnetic attraction member; 17-a box body; 171-a microswitch; 172-oblique blocks; 173-controlling the switch; 174-indicator light; 175-a power connection port; 17 a-a second magnetic attraction member; 18-a power supply module; 19-a handle; 20-a movable platform; 201-background plate; 202-a chute; 203-mounting an assembly; 2031-a mounting plate; 2032-clamp blocks; 2032 a-clamp block body; 2032a 1-mounting groove; 2032 b-platen; 2032 c-foam; 2032 d-magnets; 2033-a support plate; 204-a handle; 2041-first grooves; 200-portable optical fiber color recognition system.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly described below with reference to the drawings in the embodiments of the present application. It will be apparent that the described embodiments are some, but not all, embodiments of the application. Based on the embodiments of the present application, other embodiments that may be obtained by those of ordinary skill in the art without making any inventive effort are within the scope of the present application.

Hereinafter, the terms "first," "second," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first", "a second", etc. may explicitly or implicitly include one or more such feature. In the description of the present application, unless otherwise indicated, the meaning of "a plurality" is two or more.

Furthermore, in the present application, the terms "upper," "lower," "inner," "outer," and the like are defined relative to the orientation in which the components are schematically depicted in the drawings, and it should be understood that these directional terms are relative concepts, which are used for descriptive and clarity relative thereto, and which may be varied accordingly with respect to the orientation in which the components are depicted in the drawings.

With the development of communication technology, the transmission speed of an optical fiber communication system is continuously increasing. Modern optical fiber communication systems can realize high-speed data transmission and meet the requirements of various applications. The submarine cable communication system has the important characteristics of high-speed transmission, long-distance transmission, strong anti-interference capability, high safety and the like, and plays an important role in the optical fiber communication system.

The transmission rate of a submarine cable communication system is related to the number of optical fiber pairs in the submarine cable, and the greater the number of optical fiber pairs, the higher the transmission rate. Therefore, as the transmission rate of submarine cable communication systems increases, the number of fiber pairs in the submarine cable increases. Currently, the number of fiber pairs in submarine cables has evolved from the previous 2 fiber pairs to the present 16 fiber pairs.

In different usage scenarios, the working modes of the optical fibers are different, and the working modes of the optical fibers can be distinguished by the colors of the optical fibers. Therefore, when the optical fiber is paved, the working mode of the optical fiber is determined according to the requirement of a use scene, and then the color of the corresponding optical fiber is determined according to the working mode of the optical fiber. For example, when the transmission distances are different, the colors of the employed optical fibers are different. Wherein, yellow may represent a single mode fiber, which may be used for telecommunications. Orange may represent a multimode optical fiber that may be used for short-range data transmission. In this way, during the process of laying the optical fiber, a more suitable optical fiber can be selected according to the requirements of the use scene.

With the increase of the number of optical fiber pairs and colors, it has been very difficult to distinguish the colors of the optical fibers by human eyes only, and equipment is required to assist human eyes in recognition. For example, if the fiber diameter is large, the color of the fiber can be directly recognized by human eyes. If the diameter of the optical fiber is smaller, the color of the optical fiber can be identified by the identification device. Therefore, the requirements for the use conditions of the optical fiber color recognition device are gradually increased, and some original recognition devices can only recognize objects with the minimum size of 3mm, and when the optical fiber is recognized, the optical fiber needs to be coiled for 12 circles. However, in the environment without reference light irradiation, the recognition accuracy is low.

At present, some optical fiber color recognition devices adopt an image recognition technology, so that smaller-size optical fibers can be recognized, and the colors, textures, shapes and the like of the optical fibers can be recognized in a standard environment.

However, these fiber color identification devices currently have severe requirements for the use environment. For example, if the optical fiber color recognition device is used in a closed environment which is not interfered by the factors such as ambient light and weather, the recognition accuracy of the optical fiber color recognition device is reduced if the optical fiber color recognition device is used in an open environment.

In order to solve the technical problems, the embodiment of the application provides portable optical fiber color recognition assembly equipment, which can recognize the color of an optical fiber in an open environment, is not influenced by the open environment, and effectively improves recognition accuracy.

Fig. 1 is a schematic perspective view of a portable optical fiber color recognition assembly device according to an embodiment of the present application.

Fig. 2 is a schematic structural diagram of a portable optical fiber color recognition assembly device according to an embodiment of the present application.

Fig. 3 is a schematic structural diagram of another portable optical fiber color recognition assembly device according to an embodiment of the present application.

Referring to fig. 1,2 and 3, a portable optical fiber color recognition assembly apparatus 100 according to an embodiment of the present application includes a case 10, a movable platform 20, a light source (not shown) and a first through hole 102.

Specifically, the first accommodating portion 101 is provided in the case 10. The movable platform 20 is disposed in the first accommodating portion 101, and the movable platform 20 is movable relative to the case 10.

Wherein the movable platform 20 can be moved out of the case 10 by external force. For example, when the optical fiber needs to be installed, the movable platform 20 may be removed from the first accommodating portion 101, and after the optical fiber is placed, the movable platform 20 may be transferred into the first accommodating portion 101. The box 10 can provide a closed condition for the identification of the color of the optical fiber, and the movable platform 20 can be arranged to facilitate the placement of the optical fiber by a user.

The movable platform 20 includes a background plate 201, the background plate 201 being used for placing optical fibers. In this way, the optical fiber can be placed on the background plate 201 of the first housing portion 101, and the identification of the color of the optical fiber can be performed.

In one particular implementation, the background plate 201 may be white in color. The white background plate 201 is adopted to provide a shooting background for the identification of the optical fiber colors, so that the identification of the optical fiber colors is not interfered, and the identification efficiency of the optical fiber colors is ensured.

Of course, in other specific implementations, the background plates 201 with different colors may be matched according to different optical fibers, so that the optical fiber colors are obviously compared, and the background plates 201 are made of homogeneous high-density materials.

In one particular implementation, the light source may include a plurality of light emitting diodes (LIGHT EMITTING diodes, LEDs). The LED lamp bead is small in size and light in weight, the whole weight of the portable optical fiber color recognition assembly equipment 100 can be effectively reduced, the LED response speed is high, and light source support can be provided for recognition of optical fiber colors in time.

The light source is disposed in the case 10, and the illumination direction of the light source is toward the movable platform 20. Thus, during the process of identifying the color of the optical fiber, a constant light source environment can be provided for identifying the color of the optical fiber by turning on the light source.

The first through hole 102 is provided on the case 10. The side of the case 10 facing away from the first receiving portion 101 may be used to mount a mobile terminal that recognizes the color of the optical fiber. The first through hole 102 is opposite to the background plate 201, so that, when the light source is turned on during the optical fiber color recognition, the projection of the first through hole 102 along the irradiation direction of the light source falls on the background plate 201. The image pickup device of the mobile terminal may take an optical fiber picture or an optical fiber video located on the background plate 201 along the illumination direction through the first through hole 102, thereby identifying the color of the optical fiber.

The portable optical fiber color recognition assembly equipment 100 provided by the embodiment of the application can provide a closed condition for optical fiber color recognition, is not influenced by external environment, provides a stable recognition environment for optical fiber color recognition under the conditions that the color of the optical fiber is difficult to recognize in a submarine cable mass production stage, submarine cable construction and delivery site and relatively complex environment, and improves recognition accuracy. In addition, the operation of putting in the optical fiber is simpler and more convenient, the working efficiency is improved, and the convenience is higher.

The case 10 provided in the embodiment of the present application may be a split type structure or an integral type structure.

With continued reference to fig. 1, the case 10 shown in fig. 1 may be of unitary construction or may be of split construction in a snap-fit configuration.

In one particular implementation, with continued reference to fig. 2 and 3, the movable platform 20 may include a handle 204, a chute 202, and a mounting assembly 203.

In this implementation manner, the box body 10 may be a split structure, that is, the box body 10 includes a box cover 105 and a box body 17, where the box cover 105 is rotatably covered on the box body 17, a side of the box cover 105 facing away from the box body 17 is used for installing a mobile terminal, and the box body 17 is provided with a first accommodating portion 101, so that after the box cover 105 is covered on the box body 17, a closed identification environment is provided for optical fiber identification.

The chute 202 is disposed on the inner wall of the case 17 of the case 10, and the movable platform 20 can slide along the chute 202 relative to the case 17.

A mounting assembly 203 is slidably disposed on the chute 202 for mounting an optical fiber.

The handle 204 is connected to the mounting assembly 203, and the body 17 of the case 10 includes the notch 103, and the handle 204 is slidably disposed in the notch 103. Thus, as shown in FIG. 2, in the non-moved state of the movable platform 20, the handle 204 is positioned within the notch 103. As shown in fig. 3, in the moving state of the movable platform 20, the handle 204 is located outside the notch 103.

In this way, the portable optical fiber color recognition assembly apparatus 100 provided in the embodiment of the present application may perform the installation of the optical fiber in the following two ways:

Mode one: the optical fiber is installed without opening the cap 105. First, the user can pull out the handle 204, causing the mounting assembly 203 to be pulled out along the chute 202 with the handle 204 from the first container 101. The user may then place the fiber on the mounting assembly 203, after completing the installation, push the handle 204, causing the handle 204 to push the mounting assembly 203 along the chute 202 into the first receptacle 101 until the handle 204 is reset into the notch 103.

Mode two: the lid 105 is opened. The user can open the box cover 105, place the optical fiber on the installation component 203, and lock the box cover 105 after the installation is completed. In this way, the user does not need to pull the handle 204.

The two modes improve the use convenience of the portable optical fiber color recognition assembly equipment 100, and the optical fiber installation mode can be selected according to specific use environments. For example, if the lid 105 is not easily opened in a small space, the optical fiber may be mounted on the mounting assembly 203 in a first manner. For example, if the open environment or working space is wide, the second mode may be adopted, and the optical fiber is mounted on the mounting assembly 203 after the lid 105 is opened.

With continued reference to fig. 2 and 3, the notch 103 may be provided on the right side of the case 17, which facilitates the right-hand pushing and pulling of the movable platform 20 by the user, satisfying the right-hand usage habits of most users.

Of course, in other specific implementations, the notch 103 may also be provided on the left side.

With continued reference to fig. 2 and 3, the handle 204 is provided with a first groove 2041, the first groove 2041 extending along the height direction of the handle 204, the body 17 of the box 10 is provided with a second groove 104, and the second groove 104 is disposed at the opposite end of the notch 103 along the direction of penetration of the optical fiber. In other words, the first recess 2041 and the second recess 104 are provided on opposite sides of the case 17. For example, the first grooves 2041 and the second grooves 104 may be provided at both left and right sides of the case 17, respectively.

Specifically, the first groove 2041 and the second groove 104 are used for threading an optical fiber. Thus, when the optical fiber is inserted, the optical fiber can be inserted into the case 17 from the first groove 2041 and then be inserted out from the second groove 104. It is also possible to pass the optical fibers from the second recess 104 into the cassette body 17 and out of the first recess 2041.

Wherein the first recess 2041 and the second recess 104 may be the same height. In this way, the portion of the optical fiber located on the movable platform 20 can be ensured to be in a horizontal state.

In a specific implementation, the bottoms of the first groove 2041 and the second groove 104 are each provided with a chamfer, so as to ensure the installation stability of the optical fiber.

In a specific implementation, the handle 204 may include a bezel and a handle portion disposed on the bezel, the first recess 2041 being provided on the bezel, through which a user may pull the movable platform 20.

Of course, other forms of handles may be provided, such as a flap handle with a first recess 2041 formed therein and a recess formed in the middle thereof through which a user may pull the movable platform 20.

With continued reference to fig. 2 and 3, the lid 105 may be magnetically engaged with the body 17. Specifically, the box cover 105 may be provided with a first magnetic attraction member 105a, the box body 17 may be provided with a second magnetic attraction member 17a, and the positions of the first magnetic attraction member 105a and the second magnetic attraction member 17a are opposite. Thus, when the box cover 105 is buckled on the box body 17, the first magnetic attraction piece 105a and the second magnetic attraction piece 17a are in magnetic attraction fit, so that buckling compactness is ensured.

The first magnetic attraction piece 105a may be a magnet, the second magnetic attraction piece 17a may be a iron block, or the first magnetic attraction piece 105a may be an iron block, the second magnetic attraction piece 17a may be a magnet, or the first magnetic attraction piece 105a and the second magnetic attraction piece 17a are both magnets, but have different magnetic properties.

When the cover 105 and the case body 17 are magnetically engaged, the number of the first magnetic attraction pieces 105a and the second magnetic attraction pieces 17a may be two, respectively.

Of course, in other specific implementations, the lid 105 and the body 17 may also be snapped together in the form of a snap fit.

With continued reference to fig. 2 and 3, the portable fiber optic color identification assembly device 100 further includes a compact 1064, a micro-switch 171, and a power module 18.

The pressing block 1064 is disposed on the box cover 105 and protrudes out of the wall surface of the box cover 105. The micro switch 171 is disposed on the case 17, and the pressing block 1064 is located opposite to the micro switch 171. When the box cover 105 is buckled on the box body 17, the pressing block 1064 toggles the elastic piece of the micro switch 171, so that the micro switch 171 is toggled, and the current is conducted. When the micro switch 171 is toggled by the press block 1064, the light source is turned on. Wherein, the setting height of the shell fragment of micro-gap switch 171 is higher than the height of lateral wall, and briquetting 1064 of being convenient for stirs the shell fragment. When the cover 105 is opened, the pressing block 1064 gradually moves toward a direction away from the spring plate until the pressing block 1064 is separated from the spring plate, and the micro switch 171 turns off the light source.

Specifically, the micro switch 171 is electrically connected to the light source.

The case 10 further includes a second receiving portion 1065, and the second receiving portion 1065 is disposed on the case 17. The first accommodation portion 101 and the second accommodation portion 1065 are provided up and down along the longitudinal direction of the case 10. The first accommodating portion 101 and the second accommodating portion 1065 are separated by the partition plate 1066, so that the first accommodating portion 101 and the second accommodating portion 1065 serve as independent installation spaces, and the respective internal working components are guaranteed not to interfere in the working process.

Specifically, the power module 18 is disposed in the second accommodating portion 1065, and the power module 18 is configured to provide power to the light source. In this way, the power module 18 is provided independently of the movable platform 20, and the two do not interfere during operation. A cover plate 1069 is further disposed in the second accommodating portion 1065, where the cover plate 1069 covers the power supply module 18. Thus, the power supply module 18 can be fixed, other electric devices and circuit structures in the second accommodating part 1065 can be covered, the user is prevented from getting an electric shock by mistake, and the attractive and neat interior of the second accommodating part 1065 is ensured, and meanwhile, the use and installation properties are also ensured.

In a specific implementation manner, the power supply module 18 is a waterproof battery pack, the second accommodating portion 1065 is provided with a dedicated slot for the power supply module 18, and the cover plate 1069 may be made of an aluminum alloy material and is fixed above the power supply module 18 by screws.

The portable optical fiber color identification assembly device 100 may further include a handle 19, the handle 19 being disposed on the housing 17. The rotary connection part of the box cover 105 and the box body 17 can be opposite to the handle 19, and the handle 19 is arranged, so that the portable optical fiber color recognition assembly device 100 can be extracted and moved by a single hand of a user.

In a specific implementation, the box body 10 has a structure with a wide top and a narrow bottom along the direction that the junction of the box cover 105 and the box body 17 extends towards the handle 19, so that the overall weight of the box body 10 can be effectively reduced. Moreover, the lower narrow structure is also convenient for the user to grasp. That is, the user can move the portable optical fiber color recognition assembly device 100 through the handle 19, and can grasp the case 10 with one hand, thereby facilitating the use habits of different users.

Fig. 4 is a schematic structural diagram of a movable platform according to an embodiment of the present application.

Fig. 5 is an exploded view of a movable platform according to an embodiment of the present application.

Referring to fig. 4 and 5, the mounting assembly 203 includes a mounting plate 2031, two clamping blocks 2032 and a support plate 2033.

A mounting plate 2031 is slidably disposed on the chute 202 and is connected at one end to the handle 204. Thus, when the handle 204 is pulled, the mounting plate 2031 is pulled together. Wherein the clamping block 2032, the support plate 2033 and the background plate 201 are provided on the mounting plate 2031.

The clamping blocks 2032 are provided on both sides of the background plate 201 for clamping and fixing the optical fibers so that the optical fibers inserted into the first recess 2041 and the second recess 104 can be stably positioned on the mounting plate 2031. Therefore, the optical fiber color can be conveniently identified, and the influence on the identification effect and the identification efficiency caused by the shaking of the light optical fiber is avoided.

The support plate 2033 is provided on a side close to the second recess 104. In this way, the optical fiber of the non-detection portion located in the first accommodation portion 101 can be located on the support plate 2033, avoiding damage caused by dropping of the optical fiber.

In some possible implementations, the movable platform 20 may further be provided with a stopper (not shown in the drawings) for limiting the moving distance of the mounting plate 2031.

In one possible implementation, a stopper may be provided on a side of the mounting plate 2031 remote from the first recess 2041. When the mounting plate 2031 is driven by the handle 204 to generate relative displacement with the box body 17, the distance between the limiting block and the notch 103 is gradually reduced until the limiting block contacts with the box wall near the notch 103 and is blocked by the box wall, so as to limit the drawing distance of the movable platform 20 and prevent the movable platform 20 from falling off due to overlarge sliding distance.

Of course, in other specific implementations, the limiting block may be disposed at other positions.

With continued reference to fig. 5, the clamping block 2032 includes a clamping block body 2032a, a pressing plate 2032b, foam 2032c, and a magnet 2032d.

The clamping block body 2032a is mounted on the mounting plate 2031, a mounting groove 2032a1 is formed in the surface of the clamping block body 2032a, the mounting groove 2032a1 is used for mounting optical fibers, and the extending direction of the mounting groove 2032a1 coincides with the connecting line direction of the first groove 2041 and the second groove 104.

In other words, the extending direction of the installation groove 2032a1 is the same as the direction in which the optical fiber is inserted. For example, the optical fiber may sequentially penetrate the first groove 2041, the installation groove 2032a1, and the second groove 104 along the penetration direction.

In a specific implementation, the groove bottom cross section of the mounting groove 2032a1 may be circular, which is advantageous for better protecting the optical fiber. The depth of the installation groove 2032a1 may be 0.5mm and the groove width may be 1.8mm.

The pressing plate 2032b is rotatably fastened on the clamping block body 2032 a. That is, the fixation of the optical fiber can be achieved by fastening the pressing plate 2032b to the clamp block body 2032 a.

Foam 2032c is provided on the pressing plate 2032b, and foam 2032c is provided on a side of the pressing plate 2032b facing the clamp block body 2032 a. Specifically, the foam 2032c is positioned opposite the mounting groove 2032a1, and when the platen 2032b is engaged, the foam 2032c covers the mounting groove 2032a 1. That is, after the pressing plate 2032b is fastened to the clamp block body 2032a, the foam 2032c may cover the installation groove 2032a1, so that the optical fiber located in the installation groove 2032a1 cannot move along the vertical direction, and the installation stability of the optical fiber is ensured. Meanwhile, the foam 2032c is softer, so that the optical fiber can be effectively protected.

In a specific implementation manner, the foam 2032c may be made of Polyurethane (PU), and the foam 2032c made of PU is light and does not damage the optical fiber.

The magnet 2032d is disposed on the clamp block body 2032a and spaced apart from the mounting groove 2032a1, and the magnet 2032d is used for magnetically attracting the platen 2032b. Thus, when the pressing plate 2032b is fastened to the clamping block body 2032a, the magnet 2032d can magnetically attract the pressing plate 2032b, so that the foam 2032c is covered on the installation groove 2032a1, and installation stability and safety of the optical fiber are ensured. Specifically, when the pressing plate 2032b is engaged, the foam 2032c is spaced from the magnet 2032 d. In this way, the magnet 2032d and the foam 2032c are prevented from crossing or covering, and the magnetic attraction performance of the magnet 2032d is effectively ensured.

In a specific implementation, the mounting plate 2031 is screwed to the handle 204, and the background plate 201, the support plate 2033, and the two clamping blocks 2032 are all fixed to the mounting plate 2031 by screwing.

Fig. 6 is an exploded view of a box cover according to an embodiment of the present application.

Referring to fig. 6, the box cover 105 includes a cover body 1051, and a receiving groove 1052, a light distribution plate 1053, and a light guide plate 1054 provided on the cover body 1051.

Specifically, the accommodation groove 1052 is opened in an upper region of the lid body 1051, and an opening of the accommodation groove 1052 faces the background plate 201. That is, a receiving groove 1052 is opened at a side of the cover body 1051 facing the background plate 201. Thus, the light source is embedded in the accommodation groove 1052, and the light generated by the light source can be irradiated on the optical fiber. Wherein the first through hole 102 is located in a central region of the receiving groove 1052. That is, the light source is disposed around the first through hole 102 in a surrounding manner, and can effectively provide a stable illumination environment for the camera device of the mobile terminal when recognizing the optical fiber.

The light homogenizing plate 1053 is covered on the light source, and the columnar light of the light source can be uniformly dispersed into planar light through the light homogenizing plate 1053, so that the light is more uniform, and the illumination environment is more stable.

The light guide plate 1054 is fixed on the box cover body 1051, and the cover is arranged on the light homogenizing plate 1053, so that planar light is guided onto the background plate 201 along the illumination direction, and a stable illumination environment is provided for the identification of the optical fibers.

And the light guide plate 1054 can be fixed on the box cover body 1051 by screws, so that the stability of the light homogenizing plate 1053 positioned in the accommodating groove 1052 can be ensured.

Wherein, the light homogenizing plate 1053 is provided with a second through hole 1053a, the light guiding plate 1054 is provided with a third through hole 1054a, and the second through hole 1053a and the third through hole 1054a are the same as the first through hole 102 in terms of opening position and opening area. In other words, after the mobile terminal is mounted to the box cover body 1051, the image pickup device of the mobile terminal may sequentially pass through the first through hole 102, the second through hole 1053a, and the third through hole 1054a to perform color recognition of the optical fiber positioned on the background plate 201.

Specifically, the accommodation groove 1052 may be a square groove, and the light-homogenizing plate 1053 and the light-guiding plate 1054 are also square in shape. Thus, the shapes of the accommodation groove 1052 and the light-homogenizing plate 1053, the light-guiding plate 1054 and the background plate 201 are the same, and after the light source is installed in the accommodation groove 1052, the light after being homogenized and guided by the light-homogenizing plate 1053 and the light-guiding plate 1054 can be better irradiated on the background plate 201, so that the recognition of the color of the optical fiber is facilitated.

With continued reference to fig. 6, the first through hole 102 has a shape similar to that of two circles connected together, so that the shape of the image pickup device of the mobile terminal can be better adapted. Of course, in other specific implementations, the shape of the first through hole 102 may be a circle, a square, or other shapes.

The lid body 1051 may further include a recess 1068, the recess 1068 being disposed at an open end of the lid body 1051, wherein the open end is opposite to the connection end of the lid body 1051 and the body 17. Thus, the user can open the cap 105 through the recess 1068. Meanwhile, the concave part 1068 and the lifting handle 19 are arranged on the same side, so that the user can conveniently take, put and open the device.

Fig. 7 is an exploded view of another cap according to an embodiment of the present application.

Referring to fig. 7, the lid 105 further includes a first slider 1056, a second slider 1057, a baffle structure 1058, a first boss 1059, a guide 1060, a stop 1061, a second boss 1062, and a securing member 1063.

The first 1056 and second 1057 sliders are disposed on a side of the lid body 1051 facing away from the cassette body 17. That is, the first and second sliders 1056 and 1057 are disposed at the outer surface of the lid body 1051, and the first and second sliders 1056 and 1057 are disposed at both ends of the lid body 1051 along the length direction of the lid body 1051 for fixing both ends of the mobile terminal. By way of example, a first slider 1056 may be disposed on top of the lid body 1051 for securing the top of the mobile terminal and a second slider 1057 may be disposed on bottom of the lid body 1051 for securing the bottom of the mobile terminal.

The baffle structure 1058 is disposed at the top of the outer surface of the lid body 1051, and the baffle structure 1058 protrudes out of the surface of the lid body 1051, and the cross-sectional shape of the baffle structure 1058 is U-shaped, with the opening of the U-shape facing the bottom of the outer surface of the lid body 1051. Wherein the first slider 1056 is disposed within the U-shaped opening and the baffle structure 1058 is configured to limit the maximum displacement of the first slider 1056 along the length of the lid 105.

In this way, the baffle structure 1058 can function as a mounting and limiting feature for the first slider 1056. That is, along the length of the lid body 1051, the baffle structure 1058 is closer to the top of the lid body 1051, thereby adjusting the relative position of the first slider 1056 within the baffle structure 1058 to position the camera of the mobile terminal opposite the first aperture 102.

The positional adjustment of the first slider 1056 within the baffle structure 1058 is achieved by two first bosses 1059. Two first bosses 1059 may be disposed on both sides of the lid body 1051 in the width direction, and each first boss 1059 extends along the length direction of the lid body 1051, and the first slider 1056 is slidably disposed on the first boss 1059. Wherein the first slider 1056 is provided with a first chute (not shown) which is located opposite to the first boss 1059. In this way, the first slider 1056 can slide on the first boss 1059 along the length of the lid 105, thereby adjusting the top position of the mobile terminal such that the camera is opposite the first through-hole 102.

The guide 1060 is disposed between the top of the inner wall of the baffle structure 1058 and the first slider 1056, and the guide 1060 extends along the length of the lid body 1051.

Wherein the guide 1060 is used to adjust the relative displacement of the first slider 1056 in a longitudinal direction with respect to the lid body 1051.

Specifically, the guide member 1060 may include a guide pin and a spring, and the first slider 1056 may be moved along the length direction of the lid body 1051 by the first slider 1056 along the first protrusion 1059 and the elastic force of the spring.

In one particular implementation, two guides 1060 may be provided along the width of the lid body 1051 in order to ensure that the spring force acts uniformly on the first slider 1056.

The limiting member 1061 is disposed between the sidewall of the inner wall of the baffle structure 1058 and the first slider 1056, and the limiting member 1061 extends along the width direction of the lid body 1051.

Specifically, a waist-shaped hole 1056a is disposed on the outer side wall of the first slider 1056 corresponding to the position of the limiting member 1061, one end of the limiting member 1061 is disposed on the baffle structure 1058, and the other end is disposed in the waist-shaped hole 1056 a. Thus, the kidney-shaped aperture 1056a may be used to limit the sliding range of the first slider 1056 along the length of the lid body 1051.

In a specific implementation, the number of the limiting members 1061 may be two, and the two limiting members 1061 are respectively located at two sides of the width direction of the lid body 1051.

The two second bosses 1062 are arranged along a width direction of the lid body 1051 and extend along a length direction of the lid body 1051. The second slider 1057 is disposed on the second boss 1062 and is movable along the length of the lid body 1051 to adjust the bottom position of the mobile terminal. Wherein the second slider 1057 is provided with a second chute (not shown) which is located opposite to the second boss 1062.

Wherein the second boss 1062 may be positioned opposite the first boss 1059. That is, the central axis of the first boss 1059 located at the same side may coincide with the central axis of the second boss 1062.

In other implementations, the location of the second boss 1062 may not be opposite the location of the first boss 1059.

A securing member 1063 is disposed between the lid body 1051 and the second slider 1057, the securing member 1063 being configured to limit relative displacement of the second slider 1057 and the lid body 1051.

With continued reference to fig. 7, the fixing member 1063 may be a fixing screw, and after the position of the mobile terminal is adjusted by using the first slider 1056 and the second slider 1057, the fixing screw is screwed again to fix the second slider 1057 on the lid body 1051, so as to ensure that the camera of the mobile terminal is always opposite to the first through hole 102. After the identification of the color of the optical fiber is completed, when the mobile terminal needs to be taken out, the fixing screw is only required to be reversely rotated, so that the second slider 1057 can slide relative to the box cover body 1051.

Specifically, the number of the fixing screws may be four, two fixing screws are respectively disposed in the width direction of the box cover body 1051, and the fixing screws on the same side are disposed along the length direction of the box cover body 1051.

In this way, the upper position and the lower position of the mobile terminal can be respectively adjusted by the first slider 1056 and the second slider 1057, so that the mobile terminals with different sizes can be conveniently installed, and the adaptability of the portable optical fiber color recognition assembly device 100 provided by the embodiment of the application to the mobile terminals with different sizes can be improved.

The cover 105 may further include a magnetic attraction portion 1055, where the magnetic attraction portion 1055 is disposed between the first slider 1056 and the second slider 1057 and is disposed in a central area of the cover body 1051, and the magnetic attraction portion 1055 is used for magnetically attracting the mobile terminal.

Thus, after the mobile terminal is placed on the box cover body 1051, since the mobile terminal is adsorbed by the magnetic attraction part 1055, the mobile terminal cannot slide or slide even if the mobile terminal is fixed by the first sliding block 1056 and the second sliding block 1057, and the stability of the mobile terminal is ensured.

Meanwhile, as the movable terminal can be firmly adsorbed on the box cover body 1051, the movable terminal does not need to be taken down when the portable optical fiber color recognition assembly equipment 100 is carried, so that the repeated installation of the movable terminal is avoided, and the detection efficiency is improved.

In a specific implementation, the first slider 1056 and the second slider 1057 may be made of black Polyoxymethylene (POM), which has the advantages of high strength, high rigidity, good elasticity, and good antifriction and wear resistance, and can improve the service lives of the first slider 1056 and the second slider 1057.

Fig. 8 is a schematic perspective view of another portable optical fiber color recognition assembly device according to an embodiment of the present application.

Referring to fig. 8, the portable optical fiber color identification assembly apparatus 100 may further include a control switch 173 and an indicator light 174.

The control switch 173 is disposed on a side wall of the case 17 for controlling the state of the power supply module 18.

The second receiving portion 1065 of the case 17 may be provided with a circuit board (not shown) electrically connecting the power supply module 18 and the light source. For example, when the control switch 173 is turned on, the circuit board turns on the circuit between the power source and the power supply module 18, and at this time, after the cover 105 is buckled, the light source can be turned on. For example, when the control switch 173 is turned off, the circuit board does not conduct the circuit between the power source and the power supply module 18, and at this time, the light source is not turned on even if the cover 105 is in the fastened state. Thus, the control switch 173 can effectively control the turn-on time of the light source, so as to avoid the power loss caused by the turn-on of the light source when the micro switch 171 is touched by mistake or the box cover 105 is closed without detection.

An indicator light 174 is disposed on a side wall of the case 17 and is disposed near the control switch 173, and the indicator light 174 is used to indicate a power supply state of the power supply module 18.

The indicator light 174 is close to the control switch 173, so that the circuit connection between the circuit board and the indicator light 174 and between the circuit board and the control switch 173 can be optimized, and the space resources of the second accommodating portion 1065 can be reasonably utilized.

Specifically, the operating states of the power module 18 may include an operating state and a non-operating state, wherein the operating state may include an amount of power.

The color of the indicator light 174 is used as an example to distinguish the operating states. When the indicator light 174 is blue, it may indicate that the power supply module 18 is in a normal working state, when the indicator light 174 is red, it may indicate that the power supply module 18 is in an abnormal working state, and at this time, it may indicate that the power supply module 18 is not enough in power, so as to prompt a user to charge the power supply module or connect to a power supply for use.

Taking the number of indicator lights 174 to distinguish between operating states as an example, the number of light beads displayed by the indicator lights 174 may represent the remaining power of the power module 18. When all the beads of the indication lamp 174 are lighted, it may be indicated that the remaining power of the power supply module 18 is sufficient, and when the bead portion of the indication lamp 174 is lighted, the remaining power of the power supply module 18 may be determined according to the same proportion as the number of the lighted beads. When the external power source is connected, the indicator light 174 blinks, which may indicate that the power module 18 is in a charged state. When the external power supply is not connected, the indicator light 174 blinks to indicate that the power supply module 18 is in a state of insufficient power, so as to prompt the user to charge the power supply or use the power supply.

Wherein, external power connector 175 can set up in the position with pilot lamp 174 homonymy, the arrangement of the internal circuit of being convenient for like this is favorable to optimizing the installation space.

With continued reference to fig. 8, the portable fiber optic color identification assembly device 100 also includes a mating block 1067 and a bevel block 172.

The matching block 1067 is disposed on a side wall of the box cover 105, the oblique block 172 is disposed on a side wall of the box body 17, and the box cover 105 and the box body 17 are both disposed at a rotation connection position of the box cover 105 and the box body 17. Wherein, the position of lid 105 and box body 17 are relative, and when lid 105 is opened to the limit state, cooperation piece 1067 can laminate on the inclined plane of sloping piece 172.

That is, in the process of opening the lid 105, the engaging block 1067 is driven by the lid 105 to move toward the inclined block 172, and the distance between the engaging block 1067 and the inclined block 172 gradually decreases as the opening angle of the lid 105 increases. Until the matching block 1067 is attached to the inclined surface of the inclined block 172, the opening angle of the box cover 105 reaches the maximum opening angle, and the box cover 105 is stably positioned at the maximum opening angle through the matching of the matching block 1067 and the inclined block 172. Thus, when a user installs the optical fiber by opening the cover 105, the phenomenon that the cover 105 is unstable or the opening and closing angle is too large to cause the whole portable optical fiber color recognition assembly device 100 to topple is avoided.

In a specific implementation, with continued reference to fig. 8, the lid 105 is pin-connected to the body 17, where two pins may be provided, and a set of engaging blocks 1067 and inclined blocks 172 are provided in the middle and on both sides of the two pins, where each set includes one engaging block 1067 and one inclined block 172, so as to ensure the opening stability of the lid 105 and avoid the phenomenon that the lid 105 is toppled over.

In some possible implementations, the engagement blocks 1067 are square or rectangular.

Fig. 9 is a schematic diagram illustrating comparison between an unapplied state and an attached state of the fitting block and the oblique block according to an embodiment of the present application.

In one particular implementation, referring to fig. 9, the engagement blocks 1067 are rectangular solids. Fig. 9 (a) is a schematic cross-sectional view of the fitting block 1067 and the inclined block 172 in a non-fitting state, in which the lid 105 is in a locked state. Fig. 9 (b) is a schematic cross-sectional view showing the state where the engaging block 1067 and the inclined block 172 are attached, and the lid 105 is opened to a maximum angle. The engagement block 1067 is rotated in the S direction from the state (a) in fig. 9, and the engagement block 172 is brought into engagement with the inclined block 172 in fig. 9 (b).

Specifically, the inclined angle α of the inclined surface of the inclined block 172 may be 45 °, and since the engaging block 1067 is a cuboid, when the lid 105 is in the fastened state, the included angle β between the engaging block 1067 and the inclined block 172 is 135 °. Thus, the maximum rotation angle of the engaging block 1067 is 135 °, that is, the maximum opening angle of the lid 105 is 135 °, and when the lid 105 is opened to the maximum opening angle, the included angle between the engaging block 1067 and the inclined block 172 is 0 °, and the engaging block 1067 is attached to the inclined surface of the inclined block 172.

Corresponding to the previous embodiments of the portable fiber optic color identification assembly device 100, the present application also provides an embodiment of a portable fiber optic color identification system 200. The portable optical fiber color recognition system 200 includes the portable optical fiber color recognition assembly device 100 and the mobile terminal described above.

Fig. 10 is a block diagram of a portable optical fiber color recognition system according to an embodiment of the present application.

Referring to fig. 10, an explanation of the structure of the entire portable optical fiber color identification system 200 is provided with the inside of the case 10 and the outside of the case 10. The portable optical fiber color recognition system 200 includes the portable optical fiber color recognition assembly device 100 provided in the above-described embodiment and a mobile terminal provided on the case 10 for recognizing the color of the optical fiber. In fig. 10, the inside of the case body 10 refers to the working parts in the closed space after the case cover 105 is fastened. The outside of the case 10 refers to a working member provided on the surface of the case 10 and a mobile terminal.

To facilitate an understanding of the portable fiber color identification system 200, the installation of the optical fibers and the color identification process are described below.

In the first step, the mobile terminal is placed on the box cover body 1051 outside the box body 10, magnetically attracted to the mobile terminal by the magnetic attraction part 1055, and the first slider 1056 and the second slider 1057 are adjusted to make the image pickup device of the mobile terminal face the first through hole 102.

In the second step, the optical fibers may be placed on the background plate 201 by opening the cover 105 or pulling the movable platform 20, and the optical fibers at both ends of the background plate 201 are clamped and fixed by the clamping blocks 2032, and the supporting plate 2033 is used for supporting the optical fibers at the non-detection portion outside the background plate 201.

The execution sequence of the first step and the second step can be adjusted, that is, the sequence of installing the optical fiber and installing the mobile terminal is not fixed, and can be adjusted according to the operation habit of the user.

In the third step, the power supply module 18 may be controlled to supply power to the light source by buckling the box cover 105 or turning on the control switch 173, and turn on the light source. After the light source is turned on, the light passes through the light homogenizing plate 1053 and the light guiding plate 1054 and then irradiates the optical fiber positioned on the background plate 201.

And fourthly, the mobile terminal performs recognition of the optical fiber color by taking an optical fiber picture or video, the color recognition way can be through a recognition system arranged on the mobile terminal, a recognition result can be directly displayed through the mobile terminal, a result output value can be displayed through the mobile terminal by a personal computer ((personal computer, PC), and the display result can comprise matching data, a matching result and a recognition color.

In a specific implementation manner, the mobile terminal can enter software programming through java language to identify the color of the optical fiber.

The portable optical fiber color recognition system 200 provided by the embodiment of the application can provide a closed condition for optical fiber color recognition, is not influenced by external environment, provides a stable recognition environment for optical fiber color recognition under the conditions of difficult recognition of the optical fiber color in a submarine cable mass production stage, submarine cable construction, a submarine cable delivery site and a relatively complex environment, and improves recognition accuracy. In addition, the simple and convenient optical fiber placing operation improves the working efficiency, provides various possibilities for the optical fiber identification scheme, and has higher convenience.

It is noted that other embodiments of the application will be apparent to those skilled in the art from consideration of the specification and practice of the application disclosed herein. This application is intended to cover any variations, uses, or adaptations of the application following, in general, the principles of the application and including such departures from the present disclosure as come within known or customary practice within the art to which the application pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope of the application being indicated by the following claims.

It is to be understood that the application is not limited to the precise arrangements and instrumentalities shown in the drawings, which have been described above, and that various modifications and changes may be effected without departing from the scope thereof. The scope of the application is limited only by the appended claims.

Claims (23)

1. A portable optical fiber color identification assembly device, comprising:

the box body (10), the first accommodating part (101) is arranged in the box body (10);

a movable platform (20) disposed within the first housing (101); wherein the movable platform (20) comprises a background plate (201), the background plate (201) being used for placing optical fibers;

a light source arranged in the box body (10), wherein the irradiation direction of the light source faces the movable platform (20);

The first through hole (102) is formed in the box body (10); wherein, one side of the box body (10) facing away from the first accommodating part (101) is used for installing a mobile terminal for identifying the color of the optical fiber; the first through hole (102) is opposite to the background plate (201) so that the camera device of the mobile terminal recognizes the color of the optical fiber through the first through hole (102).

2. The portable optical fiber color recognition assembly apparatus of claim 1, wherein,

The movable platform (20) comprises:

The sliding groove (202) is formed in the inner wall of the box body (10);

A mounting assembly (203) slidably disposed on the chute (202) for mounting the optical fiber;

a handle (204) connected to the mounting assembly (203); the box body (10) comprises a notch (103), and the handle (204) is slidably arranged at the notch (103).

3. The portable optical fiber color recognition assembly apparatus of claim 2 wherein,

The handle (204) is provided with a first groove (2041), and the first groove (2041) extends along the height direction of the handle (204); the box body (10) is provided with a second groove (104), and the second groove (104) is arranged at the opposite end of the notch (103) along the penetrating direction of the optical fiber; wherein the first groove (2041) and the second groove (104) are used for threading the optical fiber.

4. A portable optical fiber color identification assembly device according to claim 3, characterized in that the mounting assembly (203) comprises:

a mounting plate (2031) slidably disposed on the chute (202), one end of the mounting plate (2031) being connected to the handle (204);

The two clamping blocks (2032) are arranged on the mounting plate (2031), and the two clamping blocks (2032) are respectively positioned on two sides of the background plate (201); wherein the clamping block (2032) is used for fixing the optical fiber;

A support plate (2033) disposed on the mounting plate (2031), the support plate (2033) disposed proximate to the second recess (104); wherein the support plate (2033) is for supporting the optical fiber.

5. The portable optical fiber color recognition assembly device of claim 4, wherein,

The clamp block (2032) includes:

A clamping block body (2032 a) arranged on the mounting plate (2031); wherein, a mounting groove (2032 a 1) is formed on the surface of the clamping block body (2032 a), and the mounting groove (2032 a 1) is used for mounting the optical fiber;

a pressing plate (2032 b) rotatably buckled on the clamping block body (2032 a);

a foam (2032 c) disposed on the platen (2032 b) and the foam (2032 c) is opposite to the mounting groove (2032 a 1), wherein, when the platen (2032 b) is snapped, the foam (2032 c) is configured to cover the mounting groove (2032 a 1);

A magnet (2032 d) arranged on the surface of the clamping block body (2032 a) and spaced from the mounting groove (2032 a 1), wherein the magnet (2032 d) is used for magnetically attracting the pressing plate (2032 b); when the pressing plate (2032 b) is buckled, the foam (2032 c) is further configured to be arranged at intervals with the magnet (2032 d).

6. The portable optical fiber color recognition assembly apparatus of claim 3,

The bottoms of the first groove (2041) and the second groove (104) are provided with chamfers.

7. The portable optical fiber color recognition assembly device of claim 4, wherein,

The mounting plate (2031) is connected with the handle (204) through screws.

8. The portable optical fiber color recognition assembly apparatus of claim 1, wherein,

The background plate (201) is white.

9. The portable optical fiber color recognition assembly apparatus of claim 2 wherein,

The box body (10) comprises a box cover (105) and a box body (17):

the box cover (105) is rotatably arranged on the box body (17) and is used for installing the mobile terminal;

the box body (17) is internally provided with the first accommodating part (101), and the notch (103) is formed in the box body (17).

10. The portable optical fiber color identification assembly device of claim 9, wherein the cap (105) comprises:

a lid body (1051);

A containing groove (1052) which is arranged on the box cover body (1051) and the opening of the containing groove (1052) faces the background plate (201); wherein the first through hole (102) is positioned in a central area of the accommodation groove (1052), and the light source is arranged in the accommodation groove (1052);

A light-homogenizing plate (1053) which is covered on the light source, wherein the light-homogenizing plate (1053) is provided with a second through hole (1053 a);

A light guide plate (1054) fixed on the box cover body (1051) and covered on the light homogenizing plate (1053), wherein the light guide plate (1054) is provided with a third through hole (1054 a); wherein the first through hole (102), the second through hole (1053 a) and the third through hole (1054 a) have the same open positions and open areas.

11. The portable optical fiber color recognition assembly apparatus of claim 1, wherein,

The light source comprises a plurality of LED lamp beads.

12. The portable fiber optic color recognition assembly device of claim 10, wherein,

The light guide plate (1054) is connected with the box cover body (1051) through screws.

13. The portable fiber optic color recognition assembly device of claim 10, wherein,

The accommodating groove (1052) is a square groove, and the light homogenizing plate (1053) and the light guide plate (1054) are square.

14. The portable fiber optic color recognition assembly device of claim 10, wherein,

The box cover (105) further comprises a magnetic attraction part (1055) which is arranged in the central area of the box cover body (1051), and the magnetic attraction part (1055) is used for magnetically attracting the mobile terminal.

15. The portable optical fiber color identification assembly device of claim 10, wherein the cap (105) further comprises:

The first sliding block (1056) and the second sliding block (1057) are arranged on the surface of one side, away from the box body (17), of the box cover body (1051), and the first sliding block (1056) and the second sliding block (1057) are arranged at two ends of the box cover body (1051) along the length direction of the box cover body (1051); wherein the first slider (1056) and the second slider (1057) are used to secure two ends of the mobile terminal.

16. The portable fiber optic color recognition assembly device of claim 15, wherein,

The lid (105) further comprises:

the baffle structure (1058) is arranged at the top of the outer surface of the box cover body (1051), the section of the baffle structure (1058) is U-shaped, and the opening of the U-shape faces to the bottom of the outer surface of the box cover body (1051); wherein the first slider (1056) is disposed within the U-shaped opening;

Two first bosses (1059), the two first bosses (1059) are arranged along the width direction of the box cover body (1051), each first boss (1059) extends along the length direction of the box cover body (1051), and the first sliding block (1056) is slidably arranged on the first bosses (1059); wherein the first slider (1056) moves along the length direction of the first boss (1059) relative to the lid body (1051) to adjust the top position of the mobile terminal.

17. The portable fiber optic color recognition assembly device of claim 16, wherein,

The lid (105) further comprises:

A guide (1060) disposed between the top of the inner wall of the baffle structure (1058) and the first slider (1056), the guide (1060) extending along the length of the lid body (1051);

The limiting piece (1061) is arranged between the side wall of the inner wall of the baffle structure (1058) and the first sliding block (1056), and the limiting piece (1061) extends along the width direction of the box cover body (1051).

18. The portable fiber optic color recognition assembly device of claim 17, wherein,

The lid (105) further comprises:

Two second bosses (1062) disposed on the lid body (1051), the second slider (1057) slidably disposed on the second bosses (1062); wherein the two second bosses (1062) are arranged along the width direction of the box cover body (1051), each second boss (1062) extends along the length direction of the box cover body (1051), and the second slider (1057) moves along the length direction of the second boss (1062) relative to the box cover body (1051) so as to adjust the bottom position of the mobile terminal;

And a fixing member (1063) disposed between the lid body (1051) and the second slider (1057), wherein the fixing member (1063) is configured to restrict the second slider (1057) from being displaced relative to the lid body (1051) when in a fastened state.

19. The portable fiber optic color identification assembly device of claim 9, further comprising:

A pressing block (1064) arranged on the box cover (105);

The micro switch (171) is arranged on the box body (17), and the pressing block (1064) is opposite to the micro switch (171); wherein, when the box cover (105) is buckled, the pressing block (1064) is configured to stir the micro switch (171); the micro switch (171) is configured to turn on the light source when being toggled by the pressing block (1064);

the box body (10) further comprises a second accommodating part (1065), and the first accommodating part (101) and the second accommodating part (1065) are separated by a partition plate (1066);

the portable optical fiber color recognition assembly device further comprises: -a power supply module (18), the power supply module (18) being arranged in the second housing (1065), the power supply module (18) being adapted to provide electrical energy to the light source.

20. The portable fiber optic color identification assembly device of claim 19, further comprising:

The matching block (1067) is arranged on the side wall of the box cover (105), and the matching block (1067) is close to the rotating connection part of the box cover (105) and the box body (17);

The inclined block (172) is arranged on the side wall of the box body (17), and the matching block (1067) is opposite to the inclined block (172); wherein, when the box cover (105) is opened to a limit state, the matching block (1067) is configured to be attached to the inclined surface of the inclined block (172).

21. The portable fiber optic color recognition assembly device of claim 20, wherein,

The matching block (1067) is a cube or a cuboid, and the inclined plane of the inclined block (172) is inclined at 45 degrees.

22. The portable fiber optic color identification assembly device of claim 20, further comprising:

a control switch (173) arranged on the side wall of the box body (17) and used for controlling the state of the power supply module (18);

and the indicator lamp (174) is arranged on the side wall of the box body (17) and is close to the control switch (173) and used for displaying the working state of the power supply module (18).

23. A portable optical fiber color identification system, comprising:

the portable optical fiber color identification assembly device (100) of any of claims 1-22;

And the mobile terminal is arranged on the box body (10) and is used for identifying the color of the optical fiber.