CN220526055U - LED vision net is with transmission module - Google Patents

Abstract

The utility model belongs to the technical field of optical modules, and particularly relates to an LED vision network same-transmission optical module, which comprises the following components: the optoelectronic device comprises an optoelectronic device shell at the middle part, and a functional circuit arranged at the middle part in the optoelectronic device shell, wherein one end of the functional circuit is connected with a transmitting end, the other end of the functional circuit is connected with a receiving end, the receiving end is provided with an arc-shaped structure, the upper side of the interior of the optoelectronic device shell is provided with a conductive metal strip area, sliding rails are arranged on two sides of the interior of the optoelectronic device shell towards one end of the receiving end, the end parts of the sliding rails extend to the side walls of the conductive metal strip area on the two sides of the receiving end, a flexible protection plate is connected between the sliding rails on the two sides in a sliding manner, a connecting block is arranged at the top of one end of the flexible protection plate, far away from the receiving end, of the flexible protection plate, a push block arranged at the top of the optoelectronic device shell is arranged on the upper side of the connecting block through a connecting rod, and a transverse sliding rail is arranged on the optoelectronic device shell corresponding to the connecting rod. The optical module is simple in structure, convenient to operate and good in protection function.

Description

LED vision net is with transmission module

Technical Field

The utility model belongs to the technical field of optical modules, and particularly relates to an LED vision network co-transmission optical module.

Background

The optical module consists of an optoelectronic device, a functional circuit, an optical interface and the like, wherein the optoelectronic device comprises a transmitting part and a receiving part, the optical module has the function that a transmitting end converts an electric signal into an optical signal, and a receiving end converts the optical signal into an electric signal after the optical signal is transmitted through an optical fiber. The LED light module is provided with an LED lamp in the light module, the LED lamp comprises three colors of lamps which are respectively red, green and blue, the driving voltages on the lamps of each color are different, the brightness is different, the lamps are combined together to form various colors, and the corresponding light module has 3 outputs, namely R and red; g, green output; and B, outputting blue.

Whether the LED vision network and the light transmission module or the common light module are provided with a transmitting end and a receiving end when in use, the interfaces of the transmitting end are generally all of metal strip connection structures and are directly exposed to air, and the interfaces are directly spliced into corresponding equipment interfaces when in use, and when not in use, the external metal strip interfaces lack corresponding protection measures and are often influenced by external environments, such as dust erosion, contact collision of external objects or liquid infiltration and the like, so that the subsequent connection stability of the receiving end is influenced;

therefore, in view of the above problems, the present technical solution designs an LED vision network co-transmission module.

Disclosure of Invention

The embodiment of the utility model aims to provide an LED vision network same-transmission module and aims to solve the problems.

The utility model is realized in such a way that an LED vision network and light transmission module comprises: optoelectronic device, transmitting end, receiving end; the optoelectronic device comprises an optoelectronic device shell at the middle part, and a functional circuit arranged at the middle part in the optoelectronic device shell, wherein one end of the functional circuit is connected with a transmitting end, the other end of the functional circuit is connected with a receiving end, during operation, the transmitting end converts an electric signal into an optical signal, the receiving end converts the optical signal into the electric signal after optical fiber transmission, the receiving end is provided with an arc-shaped structure, the upper side inside the receiving end is provided with a conductive metal strip area, the conductive metal strip area is utilized to be spliced with an equipment interface to be connected, the receiving of the optical signal is realized, at the moment, in order to facilitate the protection of the outer side of the receiving end, sliding rails are arranged on two sides of the conductive metal strip area at one end of the receiving end, the end of the sliding rail extends to the side walls at two sides of the conductive metal strip area at one end, a flexible protection plate is connected between the sliding manner, a connecting block is arranged at one end top of the flexible protection plate far away from the receiving end, a pushing block is arranged at the upper side of the connecting block, a pushing block arranged at the top outside the top of the optoelectronic device shell through a connecting rod, a transverse slideway is arranged on the optoelectronic device shell corresponding to the connecting rod, the connecting rod moves along the inside the sliding rail, and the sliding block is controlled by pushing the pushing block to move the flexible protection plate along the sliding rails at the two sides, so that the flexible protection plate can not influence the conductive metal strip on the whole and the receiving end is prevented from the whole.

Preferably, a spring is connected to one side of the connecting rod away from the receiving end, the end of the spring is fixed inside the housing of the optoelectronic device, and when the spring is in a free state, the end of the flexible protection plate is automatically controlled to move towards the end of the receiving end.

Preferably, the flexible protection plate is made of flexible plastic materials.

Preferably, the locating pin is installed to the inside corresponding flexible guard plate tip of slide rail, and the locating hole has been seted up to the inside slide rail end that the locating pin tip corresponds, locating pin and locating hole joint.

Preferably, an elastic telescopic rubber layer is connected between the two sides of the push block and the two ends of the inner side of the slideway

According to the LED vision network co-light transmission module provided by the utility model, the receiving end of the end part of the optoelectronic device is provided with the flexible protection plate which can be used for automatically covering the receiving end by manually expanding the receiving end and matching with the spring, so that the receiving end is fully protected before and after use, the damage influence of external impurities on the internal structure of the receiving end is reduced, meanwhile, the whole size of the design is not increased, the structure is relatively simple, and the manufacturing and use cost is low.

Drawings

Fig. 1 is a schematic perspective view of an LED vision net and light transmission module.

Fig. 2 is a schematic top view of an LED vision net and light transmission module.

Fig. 3 is a schematic structural diagram of a flexible protection plate in an LED vision network and light transmission module.

FIG. 4 is an enlarged schematic view of the structure of FIG. 1A;

in the accompanying drawings: optoelectronic device 10, transmitting end 11, receiving end 12, slideway 13, push block 14, flexible protection plate 15, connecting block 16, spring 17, locating pin 18, locating hole 19, slide rail 20.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

Specific implementations of the utility model are described in detail below in connection with specific embodiments.

As shown in fig. 1 to 4, a structure diagram of an LED vision network and light transmission module according to an embodiment of the present utility model includes: an optoelectronic device 10, an emitting end 11, a receiving end 12; the optoelectronic device 10 comprises an optoelectronic device shell at the middle part, and a functional circuit arranged at the middle part in the optoelectronic device shell, wherein one end of the functional circuit is connected with a transmitting end 11, the other end of the functional circuit is connected with a receiving end 12, during operation, the transmitting end 11 converts an electric signal into an optical signal, the receiving end 12 converts the optical signal into an electric signal after optical fiber transmission, the receiving end 12 is provided with an arc-shaped structure, the upper side inside the receiving end is provided with a conductive metal strip area, the conductive metal strip area is utilized to be spliced with an equipment interface to be connected, receiving of the optical signal is realized, at this time, in order to protect the outer side of the receiving end 12, sliding rails 20 are arranged at two sides inside the optoelectronic device shell towards one end of the receiving end 12, the end of the sliding rail 20 extends to the side walls of the two sides of the conductive metal strip area at the receiving end 12, a flexible protection plate 15 is connected between the sliding ends of the two side sliding rails 20, a connecting block 16 is arranged at the top of one end of the flexible protection plate 15, a pushing block 14 is arranged at the upper side of the connecting block 16, a pushing block 14 is arranged at the top of the connecting block outside the optoelectronic device shell, a transverse sliding rail 13 is arranged on the corresponding optoelectronic device shell, the connecting rod moves along the pushing block 13, and the inner side of the pushing block is connected with the device interface to be spliced with an equipment interface to be connected with the equipment interface, and the receiving end is not influenced by the conductive metal strip, and the whole protection device is prevented from moving along the sliding rails 12, and the whole protection is prevented from moving along the flexible protection strip 12 is not by the sliding rail 20, and has the whole protection effect is prevented from being greatly influenced by the whole.

In the embodiment of the utility model, in order to keep the flexible protection plate 15 unstressed, the outer side of the receiving end 12 can be automatically covered, one side of the connecting rod far away from the receiving end 12 is connected with a spring 17, the end part of the spring 17 is fixed in the housing of the optoelectronic device, when the spring 17 is in a free state, the end part of the flexible protection plate 15 is automatically controlled to move towards the end part of the receiving end 12, the flexible protection plate 15 is fully covered on the outer side of the receiving end 12, and when in use, the push block 14 is manually pushed to move towards the side far away from the receiving end 12, the spring 17 is compressed at the moment, and then the receiving end 12 is controlled to be inserted into a required interface;

the flexible protection plate 15 is made of flexible plastic materials, can shield and protect the receiving end 12, and has certain elasticity, so that the flexible protection plate can freely and stably move in the slide rail 20 with straight lines and arc tracks;

specifically, in order to keep the stability of the flexible protection plate 15 after moving to the receiving end 12, the end part of the flexible protection plate 15 corresponding to the inside of the sliding rail 20 is provided with a positioning pin 18, the inside of the end part of the sliding rail 20 corresponding to the end part of the positioning pin 18 is provided with a positioning hole 19, and the positioning pin 18 is clamped with the positioning hole 19, namely after the flexible protection plate 15 is controlled to completely move to the receiving end 12, the positioning pin 18 is clamped into the positioning hole 19, and at the moment, the stable shielding of the flexible protection plate 15 to the receiving end 12 can be kept.

In one example of the present utility model, to prevent external dust and foreign matter from entering the inside of the housing of the optoelectronic device along the slide 13, elastic telescopic rubber layers are connected between both sides of the push block 14 and both ends of the inner side of the slide 13, and the slide 13 is sealed at all times while the movement of the push block 14 is not affected.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the utility model.

Claims (5)

1. An LED vision network co-transmission module comprising: an optoelectronic device (10), an emitting end (11) and a receiving end (12); the optoelectronic device (10) comprises an optoelectronic device shell at the middle part, and a functional circuit arranged at the middle part in the optoelectronic device shell, wherein one end of the functional circuit is connected with an emission end (11), the other end of the functional circuit is connected with a receiving end (12), the optoelectronic device is characterized in that the receiving end (12) is provided with an arc-shaped structure, the upper side inside the receiving end (12) is provided with a conductive metal strip area, sliding rails (20) are arranged on two sides inside the optoelectronic device shell towards one end of the receiving end (12), the end parts of the sliding rails (20) extend to the side walls on two sides of the conductive metal strip area at the receiving end (12), a flexible protection plate (15) is connected between the sliding rails (20) on the two sides, a connecting block (16) is arranged at the top of one end of the flexible protection plate (15) far away from the receiving end (12), a pushing block (14) arranged at the top outside the optoelectronic device shell is arranged on the upper side of the connecting block (16) through a connecting rod, a transverse sliding rail (13) is arranged on the optoelectronic device shell corresponding to the connecting rod, and the connecting rod moves along the sliding rail (13) inside.

2. The Light Emitting Diode (LED) vision network and light transmission module according to claim 1, wherein a spring (17) is connected to one side of the connecting rod away from the receiving end (12), the end of the spring (17) is fixed inside the housing of the optoelectronic device, and when the spring (17) is in a free state, the end of the flexible protection plate (15) is automatically controlled to move towards the end of the receiving end (12).

3. An LED vision net co-transmission module according to claim 2, characterized in that the flexible protection plate (15) is made of flexible plastic material.

4. The LED vision network and light transmission module according to claim 3, wherein positioning pins (18) are installed at the ends of the flexible protection plates (15) corresponding to the inside of the sliding rail (20), positioning holes (19) are formed in the ends of the sliding rail (20) corresponding to the ends of the positioning pins (18), and the positioning pins (18) are clamped with the positioning holes (19).

5. The Light Emitting Diode (LED) vision network and light transmission module according to claim 4, wherein an elastic telescopic rubber layer is connected between two sides of the push block (14) and two ends of the inner side of the slideway (13).