CN116755195A - Acquisition control device and inspection method for rotary equipment - Google Patents

Abstract

The application belongs to the technical field of servers, and particularly relates to an acquisition control device and a detection method for rotary equipment, wherein the acquisition control device comprises: the plugging mechanism prevents impurities from entering an interface channel of the first SC coupling connector or an interface channel of the second SC coupling connector; the SC optical fiber jumper detects connectivity through a plugging mechanism; the application has the advantages that the dustproof effect on the gateway and the server is realized by arranging the plugging mechanism, the problem that impurities enter components and parts which are damaged by static electricity caused by forgetting to sleeve the dustproof cover of the corresponding SC coupling connector is solved, the plugging mechanism is convenient for detecting the connectivity of the SC optical fiber jumper, the detection efficiency is high, the operation is simple, in addition, the plugging mechanism can improve the connection strength of the SC optical fiber jumper, the gateway and the server, the SC optical fiber jumper is easy to align to an interface channel, and meanwhile, the interface channel is not easy to loosen, and the stable communication between the gateway and the server is ensured.

Description

Acquisition control device and inspection method for rotary equipment

Technical Field

The application belongs to the technical field of servers, and particularly relates to an acquisition control device and an inspection method for rotary equipment.

Background

When the acquisition control device is used in the rotating equipment for data acquisition, the data of the rotating equipment is relatively private, so that identity verification and file protection are required, and the traditional identity verification and file protection method often needs to use passwords or other forms of identity verification. These methods may be vulnerable to hacking, resulting in leakage of identity information and files. In order to enhance the encryption effect, data is increased, and the data needs to be transmitted to a server through a gateway for data processing.

The gateway is connected with the server through the SC optical fiber jumper wire, the gateway and the server are directly connected through two connectors by the traditional SC optical fiber jumper wire, but because the gateway and the server are all required to be provided with the jack in a redundant way, the jack is plugged by the dustproof cover to prevent dust, but when the SC optical fiber jumper wire is replaced and inserted into different jacks, the dustproof cover is easy to be lost, impurities enter the gateway and the server to generate static electricity, the gateway and the server are damaged, the SC optical fiber jumper wire cannot be used due to quality problems or light attenuation of the optical fiber itself, meanwhile, the connector is also a wearing part, when the gateway and the server have communication problems, the SC optical fiber jumper wire needs to be detached for detection, the detection efficiency is low, the disassembly and assembly are complex, in addition, the optical fiber communication requirement is high, the SC optical fiber jumper wire must be aligned to the jack, and the connector is loose to cause the communication problems of the gateway and the server.

Therefore, there is a need to develop a new acquisition control device and inspection method for rotating equipment to solve the above problems.

Disclosure of Invention

The application aims to provide an acquisition control device and an inspection method for rotary equipment.

In order to solve the above technical problems, the present application provides an acquisition control apparatus for a rotating device, comprising: the system comprises a gateway, a plurality of first SC coupling connectors, a plurality of SC optical fiber jumpers, a server, a plurality of second SC coupling connectors and a plurality of plugging mechanisms; the first SC coupling connectors are respectively connected with the gateway, the second SC coupling connectors are respectively connected with the server, each first SC coupling connector is connected with the corresponding second SC coupling connector through an SC optical fiber jumper wire, and each first SC coupling connector and each second SC coupling connector are movably provided with a plugging mechanism; the gateway is wirelessly connected with a plurality of mobile devices, and each mobile device scans a current scene by calling a rear camera so as to perform anchor point and file model rendering on an object which is input in advance after the object is identified, and the anchor point and the file model rendering are transmitted to a server through the gateway; when the first SC coupling connector or the second SC coupling connector is not inserted with the SC optical fiber jumper wire and the plugging mechanism blocks the interface channel of the first SC coupling connector or the interface channel of the second SC coupling connector, the plugging mechanism blocks impurities from entering the interface channel of the first SC coupling connector or the interface channel of the second SC coupling connector; when the SC optical fiber jumper is inserted into the first SC coupling connector or the second SC coupling connector and the interface channel of the first SC coupling connector or the interface channel of the second SC coupling connector is blocked by the plugging mechanism, the SC optical fiber jumper detects the connectivity through the plugging mechanism; and when the SC optical fiber jumper is inserted into the first SC coupling connector or the second SC coupling connector and the plugging mechanism butts against the outer side wall of the SC optical fiber jumper, the plugging mechanism prevents the SC optical fiber jumper from swinging and separating in the first SC coupling connector or the second SC coupling connector.

Further, the mobile device invokes the rear camera through the application program to scan the current scene; when the pre-entered object for identifying the identity of the user is detected, the application adds an anchor point to the object and renders the file model.

Further, a plurality of first installing ports are formed in the gateway and used for installing the first SC coupling connector.

Further, the first SC coupling connector includes: a first mounting frame and a first connection post; the first connecting column is installed on the first installation port through the first installation frame body, and an interface channel communicated with the inside of the gateway is formed in the first connecting column so as to be used for being connected with the SC optical fiber jumper.

Further, the SC optical fiber jumper is inserted into the first installation frame body through the first connector, and the end part of the SC optical fiber jumper penetrates through the first connector until extending into the first connecting column to be connected with the gateway.

Further, the plugging mechanism includes: a first U-shaped connector block and a first detection plate; the first detection plate is positioned in the opening of the first U-shaped plug-in block, three through holes are formed in the top of the first mounting frame body and are used for being movably inserted into the first U-shaped plug-in block and the first detection plate, and the first detection plate is movably arranged on the outer side of the interface channel on the first connecting column; the bottoms of the two ends of the first U-shaped plug-in block are respectively provided with a first flexible block, the bottom of the first detection plate is provided with a first flexible layer, and the bottom of the first flexible layer is provided with a first arc-shaped opening; when the first detection plate blocks the interface channel, the first detection plate blocks impurities from entering the interface channel; when the end face of the SC optical fiber jumper is propped against a first detection plate, the other end of the SC optical fiber jumper is led with light, and the connectivity of the SC optical fiber jumper is judged by detecting whether the first detection plate is transparent or not; when the two first flexible blocks are propped against the outer side wall of the first connector and the first flexible layer is propped against the outer side wall of the SC optical fiber jumper wire through the first arc-shaped opening, the two first flexible blocks and the first flexible layer can prevent the SC optical fiber jumper wire from swinging and separating in the interface channel through friction force.

Further, a first light guide layer is arranged on the first detection plate, and a light guide material is coated on the inner side wall of the first U-shaped plug-in block so as to be used for diffusing detection light.

Further, a plurality of second installing ports are formed in the server and used for installing the second SC coupling connector.

Further, the second SC coupling connector includes: a second mounting frame and a second connection post; the second connecting column is installed on the second installation port through the second installation frame body, and an interface channel communicated with the inside of the server is formed in the second connecting column so as to be used for being connected with the SC optical fiber jumper.

Further, the SC optical fiber jumper is inserted into the second installation frame body through the second connector, and the end part of the SC optical fiber jumper penetrates through the second connector until reaching into the second connecting column to be connected with the server.

Further, the plugging mechanism includes: the second U-shaped plug-in block and the second detection plate; the second detection plate is positioned in the opening of the second U-shaped plug-in block, three through holes are formed in the top of the second installation frame body and are used for being movably inserted into the second U-shaped plug-in block and the second detection plate, and the second detection plate is movably arranged on the outer side of the interface channel on the second connecting column; the bottoms of the two ends of the second U-shaped plug-in block are respectively provided with a second flexible block, the bottom of the second detection plate is provided with a second flexible layer, and the bottom of the second flexible layer is provided with a second arc-shaped opening; when the second detection plate blocks the interface channel, the second detection plate blocks impurities from entering the interface channel; when the end face of the SC optical fiber jumper is propped against a second detection plate, the other end of the SC optical fiber jumper is led with light, and the connectivity of the SC optical fiber jumper is judged by detecting whether the second detection plate is transparent or not; when the two second flexible blocks are propped against the outer side wall of the second connector and the second flexible layer is propped against the outer side wall of the SC optical fiber jumper through the second arc-shaped opening, the two second flexible blocks and the second flexible layer can prevent the SC optical fiber jumper from swinging and separating in the interface channel through friction force.

Further, a second light guide layer is arranged on the second detection plate, and a light guide material is coated on the inner side wall of the second U-shaped plug-in block for diffusing detection light.

In another aspect, the present application provides a method of testing an acquisition control device for a rotating apparatus as described above, comprising: when the SC optical fiber jumper is not inserted into the first SC coupling connector or the second SC coupling connector and the interface channel of the first SC coupling connector or the interface channel of the second SC coupling connector is blocked by the plugging mechanism, the plugging mechanism blocks impurities from entering the interface channel of the first SC coupling connector or the interface channel of the second SC coupling connector; when the SC optical fiber jumper is inserted into the first SC coupling connector or the second SC coupling connector and the interface channel of the first SC coupling connector or the interface channel of the second SC coupling connector is blocked by the plugging mechanism, the SC optical fiber jumper detects the connectivity of the SC optical fiber jumper by the plugging mechanism; and when the SC optical fiber jumper is inserted into the first SC coupling connector or the second SC coupling connector and the plugging mechanism butts against the outer side wall of the SC optical fiber jumper, the plugging mechanism prevents the SC optical fiber jumper from swinging and separating in the first SC coupling connector or the second SC coupling connector.

The application has the beneficial effects that the dustproof effect on the gateway and the server is achieved by arranging the plugging mechanism, the problem that impurities enter to generate static damage components caused by forgetting to sleeve the dustproof cover of the corresponding SC coupling connector is solved, the connectivity of the SC optical fiber jumper can be detected without detaching the SC optical fiber jumper through the plugging mechanism, the detection efficiency is high, the operation is simple, in addition, the plugging mechanism can improve the connection strength of the SC optical fiber jumper with the gateway and the server, the SC optical fiber jumper is easy to align to an interface channel, and meanwhile, the SC optical fiber jumper is not easy to loosen, and the stable communication between the gateway and the server is ensured.

Additional features and advantages of the application will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the application.

In order to make the above objects, features and advantages of the present application more comprehensible, preferred embodiments accompanied with figures are described in detail below.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings that are needed in the description of the embodiments or the prior art will be briefly described, and it is obvious that the drawings in the description below are some embodiments of the present application, and other drawings can be obtained according to the drawings without inventive effort for a person skilled in the art.

Fig. 1 is a block diagram of an acquisition control apparatus for a rotary device of the present application;

FIG. 2 is a block diagram of an SC fiber jumper of the present application;

FIG. 3 is a block diagram of a first joint of the present application;

FIG. 4 is a block diagram of a first SC coupling connector of the present application;

FIG. 5 is a block diagram of the plugging mechanism of the present application;

FIG. 6 is a block diagram of an SC fiber jumper of the present application installed in a first SC coupling connector;

FIG. 7 is a state diagram of the plugging mechanism of the present application plugging the interface channel;

FIG. 8 is a state diagram of the patch mechanism of the present application detecting connectivity;

fig. 9 is a state diagram of the plugging mechanism of the present application when the plugging mechanism functions as a release prevention.

In the figure:

1. a gateway;

2. a first SC coupling connector; 21. a first mounting frame; 22. a first connection post;

3. SC optical fiber jumper wire;

4. a plugging mechanism; 41. a first U-shaped connector block; 42. a first detection plate; 43. a first flexible block; 44. a first flexible layer; 441. a first arcuate port;

5. a first joint.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present application more apparent, the technical solutions of the present application will be clearly and completely described below with reference to the accompanying drawings, and it is apparent that the described embodiments are some embodiments of the present application, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

Embodiment 1, in this embodiment, as shown in fig. 1 to 9, this embodiment provides an acquisition control apparatus for a rotating device, which includes: the system comprises a gateway 1, a plurality of first SC coupling connectors 2, a plurality of SC optical fiber jumpers 3, a server, a plurality of second SC coupling connectors and a plurality of plugging mechanisms 4; the first SC coupling connectors 2 are respectively connected with the gateway 1, the second SC coupling connectors are respectively connected with the server, each first SC coupling connector 2 is connected with a corresponding second SC coupling connector through an SC optical fiber jumper 3, and a plugging mechanism 4 is movably arranged on each first SC coupling connector 2 and each second SC coupling connector; the gateway 1 is connected with a plurality of mobile devices in a wireless way, each mobile device scans the current scene by calling a rear camera so as to conduct anchor point and file model rendering on an object which is input in advance after the object is identified, and the anchor point and the file model rendering are sent to a server through the gateway 1; when the first SC coupling connector 2 or the second SC coupling connector is not inserted with the SC optical fiber jumper 3 and the plugging mechanism 4 blocks the interface channel of the first SC coupling connector 2 or the interface channel of the second SC coupling connector, the plugging mechanism 4 blocks impurities from entering the interface channel of the first SC coupling connector 2 or the interface channel of the second SC coupling connector; when the first SC coupling connector 2 or the second SC coupling connector is inserted with the SC optical fiber jumper 3 and the plugging mechanism 4 blocks the interface channel of the first SC coupling connector 2 or the interface channel of the second SC coupling connector, the SC optical fiber jumper 3 detects connectivity through the plugging mechanism 4; and when the SC optical fiber jumper 3 is inserted into the first SC coupling connector 2 or the second SC coupling connector and the plugging mechanism 4 butts against the outer side wall of the SC optical fiber jumper 3, the plugging mechanism 4 prevents the SC optical fiber jumper 3 from swinging and separating in the first SC coupling connector 2 or the second SC coupling connector.

In this embodiment, this embodiment plays the dustproof effect to gateway 1 and server through setting up grafting mechanism 4 on the one hand, overcome corresponding SC coupling connector and forget the cover shield and lead to impurity entering and produce the problem of static damage components and parts, on the other hand, need not to pull down SC fiber jumper 3 and can detect SC fiber jumper 3's connectivity through grafting mechanism 4, detection efficiency is high and easy operation, in addition external grafting mechanism 4 can improve SC fiber jumper 3 and gateway 1, the joint strength of server for SC fiber jumper 3 is easy to aim at the interface passageway, still is difficult to become flexible simultaneously, guarantee stable communication between gateway 1 and the server.

In this embodiment, the mobile device invokes the rear camera through the application program to scan the current scene; when the pre-entered object for identifying the identity of the user is detected, the application adds an anchor point to the object and renders the file model.

In this embodiment, based on the virtual reality technology and the computer vision technology, by identifying a specific object in a scene, adding an anchor point on the object, converting the file content into a model, and rendering on the anchor point.

In this embodiment, the identity of the user is verified by identifying a specific user object, so that the possible password leakage and hacking in the conventional identity verification manner are avoided. And the file content is transmitted in a model mode, which is different from the traditional file, data stream and other schemes. The authentication can be completed in a short time, and the use efficiency of the user is improved. The user is not required to remember information such as passwords, and the scene is directly scanned. The augmented reality technology is adopted, so that a user can perform identity verification and file protection through the virtual reality technology, and the method is a brand new experience.

In this embodiment, the gateway 1 is provided with a plurality of first installation ports for installing the first SC coupling connector 2.

In this embodiment, the first SC coupling connector 2 is fitted through the first mounting port, so that the first SC coupling connector 2 is connected to the gateway 1.

In this embodiment, the first SC coupling connector 2 includes: a first mounting frame 21 and a first connection post 22; the first connection column 22 is installed on the first installation port through the first installation frame 21, and the first connection column 22 is provided with an interface channel which is communicated with the inside of the gateway 1 and is used for being connected with the SC optical fiber jumper 3.

In this embodiment, the first connection column 22 is perpendicular to the first mounting port, so that the SC optical fiber jumper 3 can be conveniently inserted, the first mounting frame 21 plays a role in fixing the first connection column 22, and meanwhile, an interface channel is formed in the first connection column 22, so that the SC optical fiber jumper 3 is in butt joint with the gateway 1.

In this embodiment, the SC fiber patch cord 3 is inserted into the first mounting frame 21 through the first connector 5, and the end of the SC fiber patch cord 3 passes through the first connector 5 until it extends into the first connection post 22 to connect with the gateway 1.

In this embodiment, the first mounting frame 21 is provided with a limiting hole, and the first connector 5 is provided with a limiting buckle, so that the first connector 5 and the first mounting frame 21 are fixed in a limiting manner.

In this embodiment, the plugging mechanism 4 includes: a first U-shaped connector block 41 and a first detection plate 42; the first detection plate 42 is located in the opening of the first U-shaped connector block 41, three through holes are formed at the top of the first mounting frame 21 for movably inserting the first U-shaped connector block 41 and the first detection plate 42, and the first detection plate 42 is movably disposed at the outer side of the interface channel on the first connection column 22; the bottoms of the two ends of the first U-shaped plug-in block 41 are respectively provided with a first flexible block 43, the bottom of the first detection plate 42 is provided with a first flexible layer 44, and the bottom of the first flexible layer 44 is provided with a first arc-shaped opening 441; when the first detection plate 42 blocks the interface passage, the first detection plate 42 blocks impurities from entering the interface passage; when the end face of the SC optical fiber jumper 3 abuts against the first detection plate 42, the other end of the SC optical fiber jumper 3 guides light, and the connectivity of the SC optical fiber jumper 3 is judged by detecting whether the first detection plate 42 transmits light or not; when the two first flexible blocks 43 abut against the outer side wall of the first connector 5 and the first flexible layer 44 abuts against the outer side wall of the SC optical fiber jumper 3 through the first arc-shaped opening 441, the two first flexible blocks 43 and the first flexible layer 44 block the SC optical fiber jumper 3 from swinging and separating in the interface channel through friction force.

In this embodiment, the gateway 1 is used in a large-scale data processing device, so many first SC coupling connectors 2 are disposed on the gateway 1, and different SC optical fiber jumpers 3 need to be frequently replaced to connect with different first SC coupling connectors 2, so that a dust cover on the first SC coupling connectors 2 is easily lost, impurities enter damaged components in the gateway 1, the first detection board 42 is movably mounted on the first mounting frame 21 through the first U-shaped connector block 41, so that a dust-proof effect can be achieved, and the SC optical fiber jumpers 3 need to detect the quality and the optical attenuation of the SC optical fiber jumpers 3 when connected with the first SC coupling connectors 2, and whether the detection result is transparent can be quickly judged through the first detection board 42, when communication abnormality occurs between the gateway 1 and the server, only the corresponding first SC coupling connectors 2 and second SC coupling connectors need to be positioned, the SC optical fiber jumpers 3 need to be pulled out to conduct light guiding, so that problems occurring in the first SC coupling connectors 2 or the second SC optical fiber jumpers 3 can be quickly distinguished, or problems occurring in the SC optical fiber jumpers 3, and the first flexible blocks 43 and the SC optical fiber jumpers 44 can provide additional stable friction-proof effects on the SC optical fiber jumpers 3 and the optical fiber channels.

In this embodiment, the first U-shaped connector block 41 and the first detection plate 42 are made of hard materials, the first flexible block 43 and the first flexible layer 44 are made of soft materials, so that the first flexible block 43 and the first flexible layer 44 can be caused to open and deform when contacting the SC optical fiber jumper 3 and the first connector 5, the contact area and friction force between the first flexible block 43 and the first flexible layer 44 and the SC optical fiber jumper 3 and the first connector 5 are increased, the stability and the anti-drop effect on the SC optical fiber jumper 3 are further improved, and meanwhile, the first U-shaped connector block 41 and the first detection plate 42 also play a supporting role.

In this embodiment, the first detection board 42 is provided with a first light guiding layer, and the inner side wall of the first U-shaped connector block 41 is coated with a light guiding material, so as to be used for diffusing detection light, so that light spots can be diffused into light spots, which is helpful for quickly judging connectivity of the SC optical fiber jumper 3.

In this embodiment, the server is provided with a plurality of second mounting ports for mounting the second SC coupling connector.

In this embodiment, the second SC coupling connector is embedded through the second mounting port, so that the second SC coupling connector is connected to the server.

In this embodiment, the second SC coupling connector includes: a second mounting frame and a second connection post; the second connecting column is installed on the second installation port through the second installation frame body, and an interface channel communicated with the inside of the server is formed in the second connecting column so as to be used for being connected with the SC optical fiber jumper 3.

In this embodiment, the second spliced pole sets up perpendicularly to the second installation mouth, is convenient for insert SC fiber jumper 3, and the second installation framework plays fixed second spliced pole's effect, sets up interface channel at the second spliced pole simultaneously, realizes SC fiber jumper 3 and server butt joint.

In this embodiment, the SC fiber patch cord 3 is inserted into the second installation frame through the second connector, and the end of the SC fiber patch cord 3 passes through the second connector until extending into the second connection column to be connected with the server.

In this embodiment, the second mounting frame body is provided with a limiting hole, and the second connector is provided with a limiting buckle, so that the second connector and the second mounting frame body are limited and fixed.

In this embodiment, the plugging mechanism 4 includes: the second U-shaped plug-in block and the second detection plate; the second detection plate is positioned in the opening of the second U-shaped plug-in block, three through holes are formed in the top of the second installation frame body and are used for being movably inserted into the second U-shaped plug-in block and the second detection plate, and the second detection plate is movably arranged on the outer side of the interface channel on the second connecting column; the bottoms of the two ends of the second U-shaped plug-in block are respectively provided with a second flexible block, the bottom of the second detection plate is provided with a second flexible layer, and the bottom of the second flexible layer is provided with a second arc-shaped opening; when the second detection plate blocks the interface channel, the second detection plate blocks impurities from entering the interface channel; when the end face of the SC optical fiber jumper 3 is propped against a second detection plate, the other end of the SC optical fiber jumper 3 is led with light, and the connectivity of the SC optical fiber jumper 3 is judged by detecting whether the second detection plate is transparent or not; when the two second flexible blocks are propped against the outer side wall of the second connector and the second flexible layer is propped against the outer side wall of the SC optical fiber jumper 3 through the second arc-shaped opening, the two second flexible blocks and the second flexible layer can prevent the SC optical fiber jumper 3 from swinging and separating in the interface channel through friction force.

In this embodiment, the server is used for a large-scale data processing device, so many second SC coupling connectors are set on the server, and different SC optical fiber jumpers 3 need to be frequently replaced to connect with different second SC coupling connectors, so that dust covers on the second SC coupling connectors are easily lost, impurities enter damaged components in the server, the second detection plate is movably mounted on the second mounting frame body through the second U-shaped connecting block, so that the effect of dust prevention can be achieved, the quality and the light attenuation of the SC optical fiber jumpers 3 need to be detected when the second SC coupling connectors are connected, the detection result can be rapidly judged through whether the second detection plate transmits light, in addition, the second flexible block and the second flexible layer provide additional friction force for the SC optical fiber jumpers 3, the SC optical fiber jumpers 3 can be prevented from swinging and separating in an interface channel, and the effect of stability and anti-drop is achieved.

In this embodiment, the second U-shaped connector block and the second pick-up plate are hard materials, and the second flexible block and the second flexible layer are soft materials, so that the second flexible block and the second flexible layer can be promoted to open and deform when contacting the SC optical fiber jumper 3 and the second connector, the contact area and friction force between the second flexible block and the second flexible layer and the SC optical fiber jumper 3 and the second connector are increased, the stability and anti-drop effect on the SC optical fiber jumper 3 is further improved, and meanwhile, the second U-shaped connector block and the second pick-up plate also play a supporting role.

In this embodiment, a second light guiding layer is disposed on the second detection board, and a light guiding material is coated on an inner side wall of the second U-shaped connector block, so as to be used for diffusing detection light, and light spots can be diffused into light spots, which is helpful for rapidly judging connectivity of the SC optical fiber jumper 3.

Embodiment 2, on the basis of embodiment 1, the present embodiment provides a test method employing the acquisition control apparatus for a rotary device as provided in embodiment 1, comprising: when the first SC coupling connector 2 or the second SC coupling connector is not inserted with the SC optical fiber jumper 3 and the plugging mechanism 4 blocks the interface channel of the first SC coupling connector 2 or the interface channel of the second SC coupling connector, the plugging mechanism 4 blocks impurities from entering the interface channel of the first SC coupling connector 2 or the interface channel of the second SC coupling connector; when the SC optical fiber jumper 3 is inserted into the first SC coupling connector 2 or the second SC coupling connector and the interface channel of the first SC coupling connector 2 or the interface channel of the second SC coupling connector is blocked by the plugging mechanism 4, the SC optical fiber jumper 3 detects the connectivity through the plugging mechanism 4; and when the SC optical fiber jumper 3 is inserted into the first SC coupling connector 2 or the second SC coupling connector and the plugging mechanism 4 butts against the outer side wall of the SC optical fiber jumper 3, the plugging mechanism 4 prevents the SC optical fiber jumper 3 from swinging and separating in the first SC coupling connector 2 or the second SC coupling connector.

In summary, the application has the dustproof effect on the gateway and the server by arranging the plugging mechanism, so that the problem that impurities enter components and parts damaged by static electricity caused by forgetting to sleeve the dustproof cover of the corresponding SC coupling connector is solved, and on the other hand, the connectivity of the SC optical fiber jumper can be detected without detaching the SC optical fiber jumper through the plugging mechanism, the detection efficiency is high and the operation is simple, and in addition, the plugging mechanism can improve the connection strength of the SC optical fiber jumper, the gateway and the server, so that the SC optical fiber jumper is easy to align to an interface channel, and meanwhile, the SC optical fiber jumper is not easy to loosen, and the stable communication between the gateway and the server is ensured.

The components (components not illustrating the specific structure) selected in the present application are common standard components or components known to those skilled in the art, and the structures and principles thereof are known to those skilled in the art through technical manuals or through routine experimental methods.

In the description of embodiments of the present application, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present application will be understood in specific cases by those of ordinary skill in the art.

In the description of the present application, it should be noted that the directions or positional relationships indicated by the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present application and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present application. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the several embodiments provided by the present application, it should be understood that the disclosed systems, devices, and methods may be implemented in other manners. The above-described apparatus embodiments are merely illustrative, for example, the division of the units is merely a logical function division, and there may be other manners of division in actual implementation, and for example, multiple units or components may be combined or integrated into another system, or some features may be omitted, or not performed. Alternatively, the coupling or direct coupling or communication connection shown or discussed with each other may be through some communication interface, device or unit indirect coupling or communication connection, which may be in electrical, mechanical or other form.

The units described as separate units may or may not be physically separate, and units shown as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the units may be selected according to actual needs to achieve the purpose of the solution of this embodiment.

In addition, each functional unit in the embodiments of the present application may be integrated in one processing unit, or each unit may exist alone physically, or two or more units may be integrated in one unit.

With the above-described preferred embodiments according to the present application as an illustration, the above-described descriptions can be used by persons skilled in the relevant art to make various changes and modifications without departing from the scope of the technical idea of the present application. The technical scope of the present application is not limited to the description, but must be determined according to the scope of claims.

Claims (13)

1. An acquisition control device for a rotary apparatus, comprising:

the system comprises a gateway, a plurality of first SC coupling connectors, a plurality of SC optical fiber jumpers, a server, a plurality of second SC coupling connectors and a plurality of plugging mechanisms; wherein the method comprises the steps of

The first SC coupling connectors are respectively connected with the gateway, the second SC coupling connectors are respectively connected with the server, each first SC coupling connector is connected with the corresponding second SC coupling connector through an SC optical fiber jumper wire, and each first SC coupling connector and each second SC coupling connector are movably provided with a plugging mechanism;

the gateway is wirelessly connected with a plurality of mobile devices, and each mobile device scans a current scene by calling a rear camera so as to perform anchor point and file model rendering on an object which is input in advance after the object is identified, and the anchor point and the file model rendering are transmitted to a server through the gateway;

when the first SC coupling connector or the second SC coupling connector is not inserted with the SC optical fiber jumper wire and the plugging mechanism blocks the interface channel of the first SC coupling connector or the interface channel of the second SC coupling connector, the plugging mechanism blocks impurities from entering the interface channel of the first SC coupling connector or the interface channel of the second SC coupling connector;

when the SC optical fiber jumper is inserted into the first SC coupling connector or the second SC coupling connector and the interface channel of the first SC coupling connector or the interface channel of the second SC coupling connector is blocked by the plugging mechanism, the SC optical fiber jumper detects the connectivity through the plugging mechanism; and

when the SC optical fiber jumper is inserted into the first SC coupling connector or the second SC coupling connector and the plugging mechanism butts against the outer side wall of the SC optical fiber jumper, the plugging mechanism prevents the SC optical fiber jumper from swinging and separating in the first SC coupling connector or the second SC coupling connector.

2. The acquisition control device for a rotary apparatus according to claim 1,

the mobile device calls a rear camera through an application program to scan a current scene;

when the pre-entered object for identifying the identity of the user is detected, the application adds an anchor point to the object and renders the file model.

3. The acquisition control device for a rotary apparatus according to claim 1,

and a plurality of first mounting ports are formed in the gateway and used for mounting the first SC coupling connector.

4. The acquisition control device for a rotary apparatus as set forth in claim 3, wherein,

the first SC coupling connector includes: a first mounting frame and a first connection post;

the first connecting column is installed on the first installation port through the first installation frame body, and an interface channel communicated with the inside of the gateway is formed in the first connecting column so as to be used for being connected with the SC optical fiber jumper.

5. The acquisition control device for a rotary apparatus as set forth in claim 4, wherein,

the SC optical fiber jumper is inserted into the first installation frame body through the first connector, and the end part of the SC optical fiber jumper penetrates through the first connector until extending into the first connecting column to be connected with the gateway.

6. The acquisition control device for a rotary apparatus as set forth in claim 5, wherein,

the plug-in mechanism includes: a first U-shaped connector block and a first detection plate;

the first detection plate is positioned in the opening of the first U-shaped plug-in block, three through holes are formed in the top of the first mounting frame body and are used for being movably inserted into the first U-shaped plug-in block and the first detection plate, and the first detection plate is movably arranged on the outer side of the interface channel on the first connecting column;

the bottoms of the two ends of the first U-shaped plug-in block are respectively provided with a first flexible block, the bottom of the first detection plate is provided with a first flexible layer, and the bottom of the first flexible layer is provided with a first arc-shaped opening;

when the first detection plate blocks the interface channel, the first detection plate blocks impurities from entering the interface channel;

when the end face of the SC optical fiber jumper is propped against a first detection plate, the other end of the SC optical fiber jumper is led with light, and the connectivity of the SC optical fiber jumper is judged by detecting whether the first detection plate is transparent or not;

when the two first flexible blocks are propped against the outer side wall of the first connector and the first flexible layer is propped against the outer side wall of the SC optical fiber jumper wire through the first arc-shaped opening, the two first flexible blocks and the first flexible layer can prevent the SC optical fiber jumper wire from swinging and separating in the interface channel through friction force.

7. The acquisition control device for a rotary apparatus as set forth in claim 6, wherein,

the first detection plate is provided with a first light guide layer, and the inner side wall of the first U-shaped plug-in block is coated with a light guide material for diffusing detection light.

8. The acquisition control device for a rotary apparatus according to claim 1,

and a plurality of second mounting ports are formed in the server and are used for mounting the second SC coupling connectors.

9. The acquisition control device for a rotary apparatus as set forth in claim 8, wherein,

the second SC coupling connector includes: a second mounting frame and a second connection post;

the second connecting column is installed on the second installation port through the second installation frame body, and an interface channel communicated with the inside of the server is formed in the second connecting column so as to be used for being connected with the SC optical fiber jumper.

10. The acquisition control device for a rotary apparatus as set forth in claim 9, wherein,

the SC optical fiber jumper is inserted into the second installation frame body through the second connector, and the end part of the SC optical fiber jumper penetrates through the second connector until reaching into the second connecting column to be connected with the server.

11. The acquisition control device for a rotary apparatus as set forth in claim 10, wherein,

the plug-in mechanism includes: the second U-shaped plug-in block and the second detection plate;

the second detection plate is positioned in the opening of the second U-shaped plug-in block, three through holes are formed in the top of the second installation frame body and are used for being movably inserted into the second U-shaped plug-in block and the second detection plate, and the second detection plate is movably arranged on the outer side of the interface channel on the second connecting column;

the bottoms of the two ends of the second U-shaped plug-in block are respectively provided with a second flexible block, the bottom of the second detection plate is provided with a second flexible layer, and the bottom of the second flexible layer is provided with a second arc-shaped opening;

when the second detection plate blocks the interface channel, the second detection plate blocks impurities from entering the interface channel;

when the end face of the SC optical fiber jumper is propped against a second detection plate, the other end of the SC optical fiber jumper is led with light, and the connectivity of the SC optical fiber jumper is judged by detecting whether the second detection plate is transparent or not;

when the two second flexible blocks are propped against the outer side wall of the second connector and the second flexible layer is propped against the outer side wall of the SC optical fiber jumper through the second arc-shaped opening, the two second flexible blocks and the second flexible layer can prevent the SC optical fiber jumper from swinging and separating in the interface channel through friction force.

12. The acquisition control device for a rotary apparatus as set forth in claim 11, wherein,

the second detection plate is provided with a second light guide layer, and the inner side wall of the second U-shaped plug-in block is coated with a light guide material for diffusing detection light.

13. A method of inspection employing the acquisition control device for a rotary apparatus as claimed in any one of claims 1 to 12, comprising:

when the SC optical fiber jumper is not inserted into the first SC coupling connector or the second SC coupling connector and the interface channel of the first SC coupling connector or the interface channel of the second SC coupling connector is blocked by the plugging mechanism, the plugging mechanism blocks impurities from entering the interface channel of the first SC coupling connector or the interface channel of the second SC coupling connector;

when the SC optical fiber jumper is inserted into the first SC coupling connector or the second SC coupling connector and the interface channel of the first SC coupling connector or the interface channel of the second SC coupling connector is blocked by the plugging mechanism, the SC optical fiber jumper detects the connectivity of the SC optical fiber jumper by the plugging mechanism; and

when the SC optical fiber jumper is inserted into the first SC coupling connector or the second SC coupling connector and the plugging mechanism butts against the outer side wall of the SC optical fiber jumper, the plugging mechanism prevents the SC optical fiber jumper from swinging and separating in the first SC coupling connector or the second SC coupling connector.