KR200493580Y1 - Video connector with mutually engaged two-piece plastic structure - Google Patents

Abstract

The video connector having an interconnecting two-piece plastic structure includes first and second insulating plastic parts, a circuit board and a plurality of pins; The rear end of each pin is soldered to the circuit board; The first and second insulating plastic parts are each formed with a first positioning space and a second positioning space therein; The first insulating plastic part comprises a front insertion interface at a front end and a first engagement structure at a rear end; The front insertion interface has a plurality of pin engagement grooves; The second insulating plastic part has a second engaging structure at the front end; The two insulating plastic parts are bonded together through a bonding structure; So the positioning spaces together form a positioning space for accommodating the circuit board, and the front end of each pin is positioned in the corresponding pin engagement groove.

Description

VIDEO CONNECTOR WITH MUTUALLY ENGAGED TWO-PIECE PLASTIC STRUCTURE}

The present invention relates to the structure of a video connector. More specifically, the present invention effectively increases the overall structural strength of the video connector, effectively increasing the overall structural strength of the video connector, as the circuit board is reliably positioned and coupled between two insulating plastic parts to form the core structure of the video connector. Allows to maintain the desired level of structural strength against deformation (e.g. distortion) after being repeatedly plugged and unplugged during, and each pin of the video connector remains in proper electrical connection with the circuit board after prolonged use. It relates to the structure of the DisplayPort connector that ensures that the video connector is used, and its purpose is to create an optimal video transmission effect between the computer and the display device connected by the video connector to create an optimal user experience. It is to effectively prolong the lifespan.

DisplayPort (DP) is a set of connector specifications jointly developed by personal computer and chip manufacturers. The DP specification has been recognized as a digital video interface standard by the Video Electronics Standards Association (VESA) and can be used without certification or royalty. These interface standards are mainly applied to the transmission of video signals between a video source (eg, a computer) and a display device, but also support audio, Universal Serial Bus (USB), and other types of data. The DP interface standard is designed to replace these conventional interface standards as Video Graphics Array (VGA), Digital Visual Interface (DVI), and FPD-Link (or Low-Voltage Differential Signaling (LVDS)), and can be used with active or passive adapters. It is backward compatible with HDMI (High-Definition Multimedia Interface), DVI and other conventional interface standards. In particular, the Mini DisplayPort (Mini DP) connector is currently widely used to connect desktop and laptop computers that typically have a Mini DP interface to a conventional analog VGA display or display device having the same interface as the projector has. Equipment manufacturers mainly use the Mini DP connector to help increase the flexibility of use of the end product and promote the Mini DP as a high-performance digital display interface. In general, there is a market demand for a specific product or device because a product or device has the specific characteristics required. The Mini DP connector is preferred by equipment manufacturers and the general public because it makes the cable adapter smaller, more energy efficient, less expensive, and more reliable. Thus, Mini DP connectors not only energize the connector industry, but also create new market opportunities.

Since the adapter can be integrated into the Mini DP connector and thus can be provided between the corresponding computer and display device, this convenient design makes it easier to apply the adapter to a wider variety of conventional computer and display devices; In other words, the adapter integrated into the Mini DP connector can be adapted to a wider variety of connection environments than conventionally allowed. The Mini DP connector can also be embedded in a laptop computer or extension station to serve as a connection interface. In summary, the Mini DP connector is easily adaptable to many conventional interface standards due to the following features:

1. The Mini DP connector supports a 20-pin DP interface and thus can be used for many compatible electronic devices. This undoubtedly expands the service of the connector provider and creates more development opportunities for the connector business.

2. The Mini DP connector supports a maximum bandwidth of 10.8 Gbps, as well as a transmission interface using 8-bit to 10-bit color pixels. These two functions can meet the needs of most consumers who want to use high-speed networks in their daily lives.

3. The Mini DP connector is hot-pluggable. That is, with the aid of appropriate software, a Mini DP connector, or more specifically, a hot pluggable peripheral with a connector installed, does not need to cut off the power supply to the device and as a result, without fear of burning the device or peripheral. It may be connected to and disconnected from a device (eg, a computer) during operation. Being hot-pluggable also means that the Mini DP connector can detect and use new devices at once. Undoubtedly, the aforementioned features also make the Mini DP connector very flexible to use and very convenient to use.

In addition, the high adaptability and consequent convenience of the Mini DP connector creates a wide range of equipment upgrade possibilities for the general public as well as equipment manufacturers. In this respect and inspired by it, the inventors of the present invention believe that the purchase of equipment manufacturers should lead to more demands in the future, so DP connector designers and manufacturers are not only efficient to meet a single order and their sales, but also to the future. We believe that attention should be paid to the adaptability of the DP connector in equipment upgrades. Therefore, major connector design and manufacturing companies have important problems to improve the adaptability, yield, service life and upgradeability of DP connectors, and the same problems are solved by the present invention.

In view of the shortcomings of the conventional DP connector's complex manufacturing process, the inventors of the present invention have spent years of practical experience in the development, design, and manufacturing of various video connectors in extensive research, continuous improvement, and repeated testing. And finally succeeded in devising a video connector with an interconnected two-piece plastic construction. The interconnection design enables a quick and simple assembly process in which the circuit board of the video connector is reliably positioned and bonded between two insulating plastic parts so that the circuit board and the interconnected insulating plastic part together form the core structure of the video connector. Intended to do. Thus, the circuit board effectively contributes to increasing the overall structural strength of the video connector, allowing the video connector to maintain a desired level of structural strength against deformation (e.g., distortion) after being repeatedly plugged and unplugged for a long period of time. In addition, it ensures that each pin of the video connector remains in proper electrical connection with the circuit board after prolonged use. In short, the design effectively extends the service life of the video connector, and helps to create an optimal video transmission effect between the computer and the display device connected by the video connector.

One object of the present invention is to provide a video connector having a mutually mating two-piece plastic structure. The video connector includes a first insulating plastic component, a second insulating plastic component, a circuit board and a plurality of pins. Both the first insulating plastic part and the second insulating plastic part are manufactured by injection molding a plastic insulating material, and a first positioning space and a second positioning space are respectively formed therein. The first insulating plastic part is provided with a front insertion interface at the front end and a first engaging structure at the rear end, and the front insertion interface is provided with a plurality of pin engaging grooves therein. The second insulating plastic part is provided with a second engaging structure at the front end, and a rear insertion interface is formed at the rear end. In the second coupling structure, the two coupling structures are joined together to bond the first and second insulating plastic parts together to form an insulating plastic part assembly, and the first and second positioning spaces form a positioning space together. The configuration is matched to the first coupling structure. The rear insertion interface communicates with the second positioning space. The circuit board has an upper side and a bottom side each provided with a plurality of pin contact points adjacent to the front edge of the circuit board. The pin contact is electrically connected to the circuit on the circuit board. The contact terminal at the rear end of each pin is soldered to the corresponding pin contact. Once the contact terminals at the rear end of the pins are soldered to the respective pin contacts, the circuit board and pins together form a configuration that matches the positioning space. This allows the circuit board and the pins soldered thereto to be reliably positioned in the positioning space, and the contact terminals of the front end of each pin are positioned and engaged in the corresponding pin engagement grooves.

Another object of the present invention is to provide the above-described video connector having the following additional features: a pin solder joint inspection hole is provided concave at the rear end on each of the upper side and the bottom side of the first insulating plastic part, or A pin solder joint inspection hole is provided concave at the front end on each of the upper side and the bottom side of the second insulating plastic component. In either case, the pin solder joint inspection hole, when the circuit board is positioned in the positioning space, and the contact terminals of the front end of each pin are positioned and engaged in the corresponding pin coupling groove, the pin contact on the circuit board is It communicates with the positioning space so as to accurately correspond to the pin solder joint inspection hole. This allows the solder joint between the contact terminal at the rear end of each pin and the corresponding pin contact to be exposed through the pin solder joint inspection hole on the top or bottom side of the first or second insulating plastic component. Thus, the operator on the production line can easily, quickly and accurately inspect the solder quality of the joint between the contact terminal at the rear end of each pin and the corresponding pin contact on the circuit board, by visual or inspection equipment, respectively. To ensure that the pins of are kept in proper electrical connection with the circuit board. The purpose is to achieve optimal video transmission effect between equipment connected by video connectors.

Another object of the present invention is to provide the above-described video connector having the following additional features: on each of the upper side and the bottom side of the insulating plastic component assembly, it extends along the longitudinal direction of the insulating plastic component assembly and includes two of the insulating plastic body. Two first engaging grooves each adjacent to the lateral edges of the two are concavely provided. Further, the video connector further includes two elastic engagement members, each of which is formed with a second engagement groove extending along the longitudinal direction of the elastic engagement member. The second engaging groove mates with the first engaging groove in a configuration such that each elastic engaging member can be coupled to a corresponding first engaging groove and displaced longitudinally along it. Further, an engaging hook adjacent to the front end is provided on the upper side of each elastic engaging member to protrude. When the video connector is plugged into or connected to the corresponding video connector socket, the mating hook is electrically connected in a fixed manner in which the video connector and video connector socket can reliably transmit video signals to each other, and are not easily separated from each other. Each and securely hooked or mated to a corresponding mating part in the video connector socket to ensure that it does not cause an interruption in signal transmission when shaken.

Another object of the present invention is to provide the above-described video connector having the following additional features: On the upper side of each elastic coupling member, a release key adjacent to the rear end is provided protruding. When it is required to unplug or disconnect the video connector from the video connector socket, the user only needs to press the release key to push the release key toward the rear end of the video connector, and the mating hooks each have a corresponding It will be released from the mating portion to allow the video connector to be disconnected from the video connector socket.

Another object of the present invention is to provide the above-described video connector having the following additional features: not only each of the first engaging grooves, but also each of the second engaging grooves have a wall provided with a plurality of braking portions. The braking portion is configured to gradually stop the elastic engagement member at an appropriate engagement position during longitudinal displacement of the elastic engagement member along the first engagement groove, allowing a user to easily plug and unplug the video connector.

Objects, technical features, and effects of the present invention may be better understood by referring to the following detailed description of some exemplary embodiments in conjunction with the accompanying drawings.
1 is an exploded perspective view of a video connector according to the present invention.
2 is a partially assembled perspective view of a video connector according to the present invention.
3 is a longitudinal sectional view of a video connector according to the present invention.
4 is a fully assembled perspective view of the video connector according to the present invention.

The present invention provides a video connector 1 having an interconnecting two-piece plastic structure. In the most preferred embodiment of the present invention, referring to FIGS. 1 to 4, the video connector 1 conforms to the DisplayPort (DP) specification, and is combined with each other to form an insulating plastic component assembly, thereby forming an insulating plastic component assembly. The first insulating plastic part (which allows the plurality of pins 30 provided to be reliably positioned in the positioning space 100 formed between the first insulating plastic part 10A and the second insulating plastic part 10B) 10A) and a second insulating plastic part 10B. Now, the circuit board 20 is reliably positioned and coupled between the first insulating plastic part 10A and the second insulating plastic part 10B, and the first and second insulating plastic parts 10A and 10B mutually coupled. Together to form the core structure of the video connector 1, the overall structural strength of the video connector 1 is effectively increased, and the video connector 1 can be maintained at a desired level after being repeatedly plugged and unplugged for a long time. , Thereby preventing deformation (eg, distortion) of the video connector 1 and ensuring that each pin 30 is maintained in an appropriate electrical connection with the circuit board 20. As a result, not only the service life of the video connector 1 is effectively extended, but also an optimal video transmission effect between the computer (not shown) and the display device (not shown) connected by the video connector 1 is achieved. Can be used to provide an optimal user experience.

In order to facilitate explanation of the shape and structure of each component of the video connector 1, the assembly relationship between the components, and the principle of operation of the video connector 1, the upper side of each component is shown in Figs. It is defined as facing upward of the video connector 1 shown in FIG. 4, and the bottom side of each component is defined as facing downward of the video connector 1 shown in FIGS. 1 to 4, and the video connector 1 ) And the front side of each component is defined as facing the lower left corner of FIGS. 1 to 4, and the rear side of the video connector 1 and each component is defined as facing the upper right corner of FIGS. 1 to 4 do. It should be understood that the configuration of the video connector 1 and its components is not limited to that shown in FIGS. 1 to 4. If the video connector 1 has an essential structure, the manufacturer can adjust the configuration of the video connector 1 and its components according to practical needs, and can produce the same effects as disclosed in the following embodiments.

In a preferred embodiment of the present invention as shown in Fig. 1, the video connector 1 having an interconnecting two-piece plastic structure, due to its small configuration, may have a problem of maintaining its structural strength and can be repeated for a long time. Structure and construction that is superior to commercially available DP connectors, which can be distorted or otherwise deformed after being plugged and unplugged into, making it difficult for the pins 30 to remain in proper electrical connection with the circuit board 20. The commercially available DP connector not only has a short service life, but also fails to provide an optimal video transmission effect between the computer and display device to which it connects and thus an optimal user experience after prolonged use. It means that you can. The video connector 1 disclosed herein, on the other hand, can be produced by the manufacturing process of a conventional DP connector with ease and rapidity and can lead to a significant increase in production efficiency and production yield, and each Ensures that the pin 30 remains properly electrically connected to the circuit 200 on the circuit board 20, so that an optimal video transmission effect between the computer and the display device connected by the video connector 1 is achieved. Can be achieved, providing an optimal user experience.

1 and 2, the video connector 1 of this preferred embodiment comprises a first insulating plastic component 10A, a second insulating plastic component 10B, a circuit board 20, and a plurality of pins ( 30). The first insulating plastic part 10A is manufactured by injection molding a plastic insulating material, a first positioning space 100A is formed therein, and a front end having a front insertion interface 102 formed therein, and a first coupling structure ( 101A) has a rear end provided. The front insertion interface 102 is provided with a plurality of pin engaging grooves 104 therein. The front insertion interface 102 and the pin engaging groove 104 communicate with the first positioning space 100A individually. The second insulating plastic part 10B is also manufactured by injection molding a plastic insulating material, and a second positioning space 100B is formed therein, and a front end and a rear insert provided with a second coupling structure 101B. The interface 103 has a rear end formed. In the second coupling structure 101B, the first coupling structure 101A and the second coupling structure 101B are coupled to each other to form the first insulating plastic part 10A and the second insulating plastic part 10B into an insulating plastic part assembly. The first positioning space 100A and the second positioning space 100B are configured to form the positioning space 100 together, and are matched with the first coupling structure 101A (Fig. 3). The rear insertion interface 103 communicates with the second positioning space 100B.

In this preferred embodiment, referring to Figs. 2 and 3, a plurality of pin contacts 21 are disposed on each of the upper and lower sides of the circuit board 20 and are adjacent to the front edge of the circuit board 20. . The pin contact 21 is electrically connected to the circuit 200 on the circuit board 20 and is configured to be soldered to the contact terminal at the rear end of the pin 30, respectively. When the contact terminal at the rear end of each pin 30 is soldered to the corresponding pin contact 21, the circuit board 20 and the pin 30 form a configuration matching the configuration of the positioning space 100 together. do. Therefore, the soldered assembly of the circuit board 20 and the pin 30 is directly mounted and positioned in the positioning space 100 until the circuit board 20 is mounted and positioned in the positioning space 100 Alternatively, it may pass through the rear insertion interface 103. In either case, the contact terminal at the front end of each pin 30 is eventually positioned and coupled to the corresponding pin engagement groove 104, and the circuit board 20 is formed with a first insulating plastic part 10A and a second It will be reliably positioned and engaged between the insulating plastic parts 10B. Therefore, by forming the core structure of the video connector 1 together with the circuit board 20 and the interconnected first and second insulating plastic parts 10A and 10B, the overall structural strength of the video connector 1 is increased. Is effectively increased. The video connector 1 will be able to maintain its structural strength at a desired level, and thus will not easily distorted or otherwise deformed after being repeatedly plugged and unplugged for a long period of time, which means that each pin 30 It is ensured that the proper electrical connection with the circuit board 20 is maintained after a long period of use. As a result, the service life of the video connector 1 is effectively extended, and an optimal video transmission effect between a computer (not shown) and a display device (not shown) connected by the video connector 1 is achieved, which is optimal. Can provide a user experience.

It should be noted that the above-described embodiment is merely a preferred embodiment of the present invention, and is by no means intended to limit the implementation of the present invention to a specific embodiment. In another embodiment of the present invention, referring to FIGS. 1 and 3, each of the upper side and the bottom side of the first insulating plastic part 10A has a pin solder joint at the rear end to meet product requirements or manufacturing process requirements. The inspection hole H may be provided concave, or instead a pin solder joint inspection hole H at the front end of each of the upper side and the bottom side of the second insulating plastic part 10B may be provided concavely. I can. In either case, the pin solder joint inspection hole H communicates with the positioning space 100. When the circuit board 20 is positioned in the positioning space 100 and the contact terminal of the front end of each pin 30 is positioned and coupled to the corresponding pin coupling groove 104, The pin contact 21 accurately corresponds to the pin solder joint inspection hole H, so that the solder joint between the contact terminal at the rear end of each pin 30 and the corresponding pin contact 21 on the circuit board 20 Is exposed through the pin solder joint inspection hole (H) on the top or bottom side of the first or second insulating plastic part (10A or 10B) and (by visual or by any of the inspection equipment (not shown)) the production line Can be easily, quickly and accurately inspected by the operator on the top, so that each pin 30 is connected with the circuit board 20 to create an optimal video transmission effect between the equipment connected by the video connector 1. Ensure that proper electrical connections are maintained.

In an embodiment of the present invention, referring to FIGS. 1 and 4, the first insulating plastic part 10A includes two pairs of first front coupling grooves 105A, and the second insulating plastic part 10B is It includes two pairs of first rear engaging grooves 105B. Each pair of first front engaging grooves 105A is provided respectively and concavely on the upper side and the bottom side of the first insulating plastic part 10A, and one of the two lateral edges of the first insulating plastic part 10A It is adjacent to and extends in the longitudinal direction of the first insulating plastic part 10A. Similarly, each pair of the first rear engaging groove 105B is provided respectively and concavely on the upper side and the bottom side of the second insulating plastic part 10B, and two sides of the second insulating plastic part 10B. Adjacent to one of the edges, it extends in the longitudinal direction of the second insulating plastic part 10B. Each pair of the first front coupling groove 105A and the corresponding pair of the first rear coupling groove 105B correspond to each other when the first insulating plastic part 10A and the second insulating plastic part 10B are joined to each other. And is configured to communicate with each other and configured to form a pair of first coupling grooves 105 together. In this embodiment of the present invention, referring to FIGS. 1 and 2, the video connector 1 further includes two elastic coupling members 40. In each of the elastic coupling members 40, a second coupling groove 405 extending along the longitudinal direction of the elastic coupling member 40 is formed. The second coupling groove 405 is matched to the first coupling groove 105 in a configuration in which each elastic coupling member 40 is coupled with the corresponding pair of first coupling grooves 105 to be displaced in the longitudinal direction. do. In addition, a coupling hook 401 adjacent to the front end is provided on the upper side of each of the elastic coupling members 40 to protrude. Once the video connector 1 is plugged into or connected to a corresponding video connector socket (not shown), the mating hook 401 is electrically connected in such a way that the video connector 1 and the video connector socket are fixed, The video signals can be stably transmitted to each other, and are not easily separated from each other and are respectively and firmly hooked or coupled to the corresponding mating portions of the video connector sockets so as not to cause an interruption in signal transmission if shaken. With continued reference to FIGS. 1 and 2, a release key 402 adjacent to the rear end is provided to protrude from the upper side of each of the elastic coupling members 40. When it is desired to unplug the video connector 1 from the video connector socket, the user only needs to press the release key 402 to push the release key 402 toward the rear end of the video connector 1, Each mating hook 401 is released from a corresponding mating portion in the video connector socket to cause the video connector 1 to be unplugged from the video connector socket. In addition, a plurality of braking portions 4051 as shown in Figs. 1 and 2 are provided not only on the wall of each of the first coupling grooves 105 but also on the wall of each of the second coupling grooves 405. When the elastic engagement member 40 is displaced in the longitudinal direction along the first engagement groove 105, each elastic engagement member 40 can be gradually stopped at an appropriate engagement position, so that the user can step by step the video connector ( 1) can be plugged or unplugged.

2 and 4, the video connector 1 further includes a metal housing 50 to better resist electromagnetic interference. The metal housing 50 has a receiving space 500 formed therein, and the receiving space allows the metal housing 50 to surround and protect the insulating plastic component assembly as well as shield the pin 30, and the pin ( 30) to prevent the video signal transmitted by external electromagnetic interference, or to prevent generating electromagnetic waves that may interfere with neighboring circuits, and matched to the insulated plastic component assembly. The metal housing 50 is formed with two engaging hook passage slots 501 corresponding to the engaging hook 401 in their respective positions. The coupling hook passage slot 501 communicates with the accommodation space 500 so that the coupling hooks 401 may pass through the coupling hook passage slots 501, respectively and are exposed from the metal housing 50. The metal housing 50 is also formed with two release key passage slots 502 corresponding respectively to the release key 402 in place. The release key passage slot 502 communicates with the accommodation space 500 so that the release key 402 may pass through the release key passage slot 502, respectively, and may be exposed from the metal housing 50.

Although the present invention disclosed herein has been described by means of specific embodiments, numerous modifications and variations can be made by those skilled in the art within the scope of the present invention described in the claims.

Claims (10)

It is a video connector with an interconnected two-piece plastic construction
As a first insulating plastic part manufactured by injection molding a plastic insulating material, the first insulating plastic part 10A has a first positioning space 100A formed therein, and the front insertion interface 102 is formed. Has an end, and has a rear end provided with a first engagement structure 101A, and the front insertion interface 102 does not expose the pin 30 from the top or bottom surface of the first insulating plastic part 10A therein. A plurality of pin engaging grooves 104 are provided, which are configured to receive at least one front end of at least one pin 30 while not having, and the front inserting interface 102 and the pin engaging groove 104 are individually provided. 1, a first insulating plastic part in communication with the positioning space (100A);
As a second insulating plastic part 10B also manufactured by injection molding a plastic insulating material, the second insulating plastic part 10B includes a circuit board 20 in a second positioning space 100B formed therein. It is configured to receive only along the longitudinal direction of 20, has a front end provided with a second engaging structure 101B, has a rear end formed with a rear insertion interface 103, and the second engaging structure 101B, The first coupling structure 101A and the second coupling structure 101B are joined to each other, thereby bonding the first insulating plastic part 10A and the second insulating plastic part 10B together to form an insulating plastic part assembly, The first positioning space 100A and the second positioning space 100B are configured to form the positioning space 100 together, and are matched to the first coupling structure 101A, and the rear insertion interface 103 is A second insulating plastic part in communication with the 2 positioning space 100B; And
A circuit board 20 having an upper side and a bottom side provided with a plurality of pin contact points 21 adjacent to the front edge of the circuit board 20, respectively, wherein the pin contact 21 is a circuit 200 on the circuit board 20 Each configured to be electrically connected to and soldered to the contact terminal of the rear end of the pin 30, and once the contact terminal of the rear end of each of the pins 30 is soldered to the corresponding one of the pin contact 21, The circuit board 20 and the pin 30 together form a configuration that matches the positioning space 100 and thus can be positioned in the positioning space 100, so that the front end of each of the pins 30 A video connector comprising a circuit board (20) that allows a contact terminal to be positioned and mated to a corresponding one of the pin coupling grooves (104). The method according to claim 1, wherein the first insulating plastic component (10A) has an upper side and a bottom side provided respectively concave with a pin solder joint inspection hole (H) at the rear end of the first insulating plastic component (10A), or The second insulating plastic component 10B has an upper side and a bottom side each of which the pin solder joint inspection hole H is provided concave at the front end of the second insulating plastic component 10B, and the pin solder joint inspection hole H ), once the circuit board 20 is positioned in the positioning space 100 and the contact terminal of the front end of each of the pins 30 is positioned and coupled to the corresponding pin coupling groove 104, the circuit The pin contact 21 on the substrate 20 precisely corresponds to the pin solder joint inspection hole H, so that the solder joint between the contact terminal at the rear end of each pin 30 and the corresponding pin contact 21 Through the pin solder joint inspection hole H on the upper side of the first insulating plastic part 10A or the second insulating plastic part 10B, or of the first insulating plastic part 10A or the second insulating plastic part 10B. A video connector in communication with the positioning space 100 so as to be exposed through the pin solder joint inspection hole H on the bottom side. The method according to claim 2, wherein each of the upper side and the bottom side of the first insulating plastic part (10A) has two first front engaging grooves (105A) each adjacent to the two lateral edges of the first insulating plastic part (10A). This is provided longitudinally and concavely, and on each of the upper side and the bottom side of the second insulating plastic part 10B, two first rear engagements each adjacent to the two lateral edges of the second insulating plastic part 10B. The groove 105B is provided longitudinally and concavely, and the first front coupling groove 105A and the first rear coupling groove 105B are provided with a first insulating plastic part 10A and a second insulating plastic part 10B. When these are joined together, the corresponding one of each of the first front coupling groove 105A and the first rear coupling groove 105B is configured to correspond and communicate with each other, so as to form the first coupling groove 105 together. Video connector. The method of claim 3, further comprising two elastic coupling members (40), each of the elastic coupling members (40) has a second coupling groove (405) formed in a longitudinal direction, and a second coupling groove (405) Is a video connector mating to the first engaging groove 105 in a configuration such that each of the resilient engaging members 40 are engageable with a corresponding one of the first engaging grooves 105 and are displaceable in the longitudinal direction along this. . The method of claim 4, wherein each of the elastic coupling members (40) has an upper side provided by the coupling hook (401) protruding, and the coupling hooks (401) are each adjacent to the front end of the elastic coupling member (40). , When the video connector 1 is connected to the corresponding video connector socket, the mating hook 401 is electrically connected in a fixed manner in which the video connector 1 and the video connector socket, and can stably transmit video signals to each other, and , So that they are not separated from each other and thus cause an interruption in signal transmission when shaken, each and securely mated to the corresponding mating part of the video connector socket. The method of claim 5, wherein a release key 402 is provided to protrude from an upper side of each of the elastic coupling members 40, and the release keys 402 are each adjacent to the rear end of the elastic coupling member 40, The engaging hooks 401 are respectively released from corresponding engaging portions in the video connector socket when the release key 402 is pressed and pushed toward the rear end of the video connector 1. The method of claim 6, wherein each of the second coupling grooves 405 as well as each of the first coupling grooves 105 define a first coupling groove 105 corresponding to each of the elastic coupling members 40. A video connector having a wall provided with a plurality of braking portions 4051 so as to be gradually stopped at the engaged position while being displaced longitudinally along the line. The method of claim 7, further comprising a metal housing (50), the metal housing (50) has a receiving space (500) formed therein, and the receiving space (500) is a metal housing (50) is an insulating plastic part A video connector mating to an insulated plastic component assembly in a configuration that surrounds and protects the assembly to shield pins (30). The method of claim 8, wherein the metal housing 50 is provided with two engaging hook passage slots 501 corresponding to the engaging hooks 401 in position, and the engaging hook passage slots 501 are formed with engaging hooks (401). A video connector in communication with the receiving space 500 to allow each of the) to pass through the engaging hook passage slot 501 and be exposed from the metal housing 50. 10. The method of claim 9, wherein the metal housing (50) is provided with two release key passage slots (502) corresponding to the release key (402) in position, and the release key passage slot (502) is a release key (402). A video connector in communication with the receiving space 500 to allow each) to pass through the release key passage slot 502 and to be exposed from the metal housing 50.

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