阅读说明：本技术 电连接器及线缆连接器组件 (Electric connector and cable connector assembly ) 是由 李华兵 黄钰 于 2019-08-16 设计创作，主要内容包括：一种电连接器及线缆连接器组件,所述电连接器包括绝缘本体、收容于所述绝缘本体内的定位件、安装于所述定位件且收容于所述绝缘本体内的导电端子、用于焊接所述导电端子的印刷电路板、绝缘内模及包覆所述绝缘本体的金属壳体。所述印刷电路板上设有焊接所述导电端子的焊接区域,所述绝缘内模包覆所述焊接区域,所述金属壳体上设有贯通所述金属壳体并位于所述绝缘内模外围的抓料口,增加所述绝缘内模与所述金属壳体之间的结合强度。(An electric connector and a cable connector assembly are provided, the electric connector comprises an insulating body, a positioning piece contained in the insulating body, a conductive terminal installed on the positioning piece and contained in the insulating body, a printed circuit board used for welding the conductive terminal, an insulating inner mold and a metal shell covering the insulating body. The printed circuit board is provided with a welding area for welding the conductive terminals, the insulating inner die covers the welding area, the metal shell is provided with a material grabbing port which penetrates through the metal shell and is positioned on the periphery of the insulating inner die, and the bonding strength between the insulating inner die and the metal shell is increased.)

1. An electrical connector (1), characterized in that: including insulator (11), accept in setting element (12) in insulator (11), install in setting element (12) and accept in conductive terminal (13) in insulator (11), be used for the welding printed circuit board (14), insulating centre form (15) and the cladding of conductive terminal (13) metal casing (16) of insulator (11), be equipped with the welding on printed circuit board (14) the welding region of conductive terminal (13), insulating centre form (15) cladding welding region, be equipped with on metal casing (16) and link up metal casing (16) and be located insulating centre form (15) outlying material mouth (1626) of grabbing.

2. An electrical connector (1) according to claim 1, characterized in that: metal casing (16) are including holding procapsid (161) of insulator (11) and certainly back casing (162) that procapsid (161) extends backward, back casing (162) include diapire (1621), with roof (1622) that diapire (1621) is relative and connect roof (1622) with both sides wall (1623) of diapire (1621), it is located to grab material mouth (1626) on lateral wall (1623).

3. An electrical connector (1) according to claim 2, characterized in that: the printed circuit board (14) is provided with a clamping block (145), and the side wall (1623) is further provided with a clamping groove (1628) matched with the clamping block (145).

4. An electrical connector (1) according to claim 1, characterized in that: the conductive terminal (13) comprises a butt joint part (131) positioned at the front end of the conductive terminal, a middle part (132) extending backwards from the butt joint part (131), a holding part (133) extending backwards from the middle part (132) and a welding part (134) extending backwards from the holding part (133), wherein the welding part (134) is welded in the welding area.

5. An electrical connector (1) according to claim 4, characterized in that: insulator (11) include main part (111), certainly plug space (112), the position that forms is sunken backward to main part (111) front surface, be located plug space (112) go up a plurality of terminal grooves (113) of lower wall, and be located plug space (112) rear and with accommodation space (114) that plug space (112) link up, butt joint portion (131) are located in plug space (112), intermediate part (132) hold in terminal groove (113), fixing portion (133) install in setting element (12), welding part (134) welding is in on printed circuit board (14), insulating centre form (15) cladding is in the periphery of welding part (134).

6. An electrical connector (1) according to claim 5, wherein: the positioning piece (12) is accommodated in the accommodating space (114) of the insulating housing (11), and is provided with a plurality of accommodating grooves (121) which are penetrated from front to back, and the holding part (133) is held in the accommodating grooves (121).

7. An electrical connector (1) according to claim 4, characterized in that: the welding area of the printed circuit board (14) is provided with a plurality of first conductive sheets (141), and the welding part (134) of the conductive terminal (13) is welded on the first conductive sheets (141).

8. An electrical connector (1) according to claim 2, characterized in that: be equipped with buckle arch (123) on setting element (12), be equipped with on diapire (1621) with buckle arch (123) matched with buckle groove (1625).

9. A cable connector assembly (100), characterized by: comprising an electrical connector (1) according to any of claims 1 to 8, a cable (2) electrically connected to the printed circuit board (14), a grounding plate (31) held at one end to the cable (2) and soldered at the other end to the printed circuit board (14), and a housing (35) enclosing at least part of the grounding plate (31) and at least part of the electrical connector (1).

10. The cable connector assembly (100) of claim 9, wherein: the grounding device also comprises conductive plastic (32) wrapping at least part of the metal shell (16) and at least part of the grounding sheet (31), and the shell (35) is sleeved on the periphery of the conductive plastic (32).

Technical Field

The invention relates to an electric connector and a cable connector assembly, and belongs to the field of electric connectors.

Background

With the increasing proliferation of consumer electronics, and the development of electronic products towards high definition, lightness and thinness, the requirements for data and audio/video transmission speed are higher and higher. In the conventional electrical connector, after the soldering portion of the conductive terminal is soldered to the printed circuit board, an insulating inner film is injection-molded in the soldering region of the printed circuit board to cover the soldering region, and then the metal housing is assembled. In the structure, the bonding strength between the printed circuit board, the insulating inner mold and the metal shell is insufficient, and the electric connector cannot meet the requirements of certain limit conditions, such as larger shearing force and other mechanical properties, in the using process.

The invention aims to provide an electric connector and a cable connector assembly which can meet the requirement of mechanical strength.

Disclosure of Invention

The invention aims to provide an electric connector with high mechanical strength and a cable connector assembly.

In order to achieve the above object, an aspect of the present invention provides an electrical connector, which includes an insulating body, a positioning element accommodated in the insulating body, a conductive terminal installed in the positioning element and accommodated in the insulating body, a printed circuit board for welding the conductive terminal, an insulating inner mold, and a metal housing covering the insulating body, wherein a welding area for welding the conductive terminal is disposed on the printed circuit board, the insulating inner mold covers the welding area, and a material catching opening penetrating through the metal housing and located at the periphery of the insulating inner mold is disposed on the metal housing.

Further, metal casing is including holding insulator's procapsid and certainly the back casing that the procapsid extends backward, back casing include the diapire, with relative roof of diapire and connection the roof with the both sides wall of diapire, grab the material mouth and be located on the lateral wall.

Furthermore, the printed circuit board is provided with a clamping block, and the side wall is also provided with a clamping groove matched with the clamping block.

Further, the conductive terminal comprises a butt-joint part at the front end thereof, a middle part extending backwards from the butt-joint part, a holding part extending backwards from the middle part and a welding part extending backwards from the holding part, and the welding part is welded in the welding area.

Further, the insulator comprises a main body part, an inserting space formed by the front surface of the main body part by recessing backwards, a plurality of terminal grooves located on the upper wall and the lower wall of the inserting space, and an accommodating space located behind the inserting space and communicated with the inserting space, wherein the butt joint part is located in the inserting space, the middle part is accommodated in the terminal grooves, the fixing part is installed in the positioning part, the welding part is welded on the printed circuit board, and the insulating inner die is coated on the periphery of the welding part.

Furthermore, the positioning member is accommodated in the accommodating space of the insulating housing, and has a plurality of accommodating grooves penetrating from front to back, and the holding portion is held in the accommodating grooves.

Furthermore, the welding area of the printed circuit board is provided with a plurality of first conductive sheets, and the welding part of the conductive terminal is welded on the first conductive sheets.

Furthermore, the positioning piece is provided with a buckle protrusion, and the bottom wall is provided with a buckle groove matched with the buckle protrusion.

Another aspect of the present invention provides a cable connector assembly, which includes the electrical connector, a cable electrically connected to the pcb, a grounding plate having one end fixed to the cable and the other end soldered to the pcb, and a housing covering at least a portion of the grounding plate and at least a portion of the electrical connector.

Furthermore, the grounding device also comprises conductive plastic wrapping at least part of the metal shell and at least part of the grounding sheet, and the shell is sleeved on the periphery of the conductive plastic.

Compared with the prior art, the metal shell of the electric connector and cable connector assembly is provided with the material grabbing port which penetrates through the metal shell and is positioned on the periphery of the insulating inner die, so that the bonding strength between the insulating inner die and the metal shell is improved.

Drawings

Fig. 1 is a perspective view of a cable connector assembly of the present invention.

Fig. 2 is a partially exploded perspective view of fig. 1 with the housing separated.

Fig. 3 is a further partially exploded perspective view of fig. 2, with the metal shell and the dielectric module further separated.

Fig. 4 is an exploded perspective view at another angle of fig. 3.

Fig. 5 is a further partially exploded perspective view of fig. 3 with the conductive plastic further separated.

Fig. 6 is an exploded perspective view at another angle of fig. 5.

Fig. 7 is a perspective view of the connector assembly of the present invention of fig. 6 with the conductive plastic, metal shell, insulating module and housing removed.

Fig. 8 is a further partially exploded perspective view of fig. 6.

Fig. 9 is an exploded perspective view at another angle of fig. 8.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. Referring to fig. 1 to 9, a cable connector assembly 100 of the present invention includes an electrical connector 1, a cable 2 and a shielding unit 3. The electric connector 1 comprises an insulating body 11, a positioning part 12 accommodated in the insulating body 11, conductive terminals 13 installed in the positioning part 12 and accommodated in the insulating body 11, a printed circuit board 14 for welding the conductive terminals 13, an insulating inner mold 15 for preventing short circuit between the conductive terminals 13, and a metal shell 16 covering the insulating body 11. The cable 2 is electrically connected to the conductive terminal 13 and has a plurality of conductive wires 21 and a braid 22. The shielding protection unit 3 includes a grounding plate 31 having one end fixed on the surface of the braid 22 and the other end welded on the printed circuit board 14, a conductive plastic 32 covering the metal shell 16 and the grounding plate 31, a metal shell 33 covering the conductive plastic 32, an insulating module 34 covering a portion of the metal shell 33, and a housing 35 covering the insulating module 34 and the metal shell 33.

Referring to fig. 5 and 8, the insulating body 11 includes a main body 111, a plug space 112 recessed rearward from a front surface of the main body 111, a plurality of terminal slots 113 located at upper and lower walls of the plug space 112, an accommodating space 114 located behind the plug space 112 and penetrating the plug space 112, and a pair of engaging portions 115 extending rearward from a rear surface of the main body 111 and located at two sides of the accommodating space 114. The terminal groove 113 extends from front to back through the main body 111 and communicates with the insertion space 112 to receive the conductive terminal 13.

As shown in fig. 9, the positioning member 12 is accommodated in the accommodating space 114 of the insulating housing 11, and has a plurality of accommodating grooves 121 penetrating from front to back and a fastening protrusion 123 extending downward from a bottom surface, and the positioning member 12 is accommodated in the accommodating space 114 and fastened between the pair of fastening portions 115.

Referring to fig. 9, the conductive terminal 13 includes a mating portion 131 at a front end thereof, an intermediate portion 132 extending rearward from the mating portion 131, a holding portion 133 extending rearward from the intermediate portion 132, and a soldering portion 134 extending rearward from the holding portion 133. The butt-joint portion 131 is located in the inserting space 112, the middle portion 132 is accommodated in the terminal groove 113, the holding portion 133 is installed in the accommodating groove 121 of the positioning member 12, the welding portion 134 is welded on the printed circuit board 14, the insulating inner mold 15 covers the periphery of the welding portion 134, and the short circuit of the welding portion 134 of the conductive terminal 13 is prevented.

Referring to fig. 8, a row of first conductive sheets 141 and a row of second conductive sheets 142 are disposed on the upper surface and the lower surface of the printed circuit board 14, the welding portion 134 of the conductive terminal 13 is welded on the first conductive sheets 141, after the welding is completed, the insulating inner mold 15 is injection-molded to cover the printed circuit board 14 with the welding portion 134, and the wire 21 of the cable 2 is welded on the second conductive sheets 142 to electrically connect the cable 2 to the conductive terminal 13. Two third conductive sheets 143 are further disposed on the upper surface of the printed circuit board 14, and the two third conductive sheets 143 are located behind the second conductive sheet 142 and located on two sides of the second conductive sheet 142 respectively. The printed circuit board 14 has two side surfaces each provided with a locking piece 145.

The area where the first conductive sheet 141 is located is defined as a first welding area, and the area where the second conductive sheet 142 is located is defined as a second welding area, in the embodiment disclosed in the present application, the insulating inner mold 15 is only injection-molded to cover the first welding area, and in other embodiments, the insulating inner mold 15 may be injection-molded to cover the first welding area and the second welding area.

Referring to fig. 8 and 9, the metal housing 16 includes a front housing 161 accommodating the insulating body 11 and a rear housing 162 extending rearward from the front housing 161, wherein the front housing 161 has a contour matching the contour of the insulating body 11, and the rear housing 162 is used for accommodating the positioning member 12, the insulating inner mold 15 and a portion of the printed circuit board 14. The rear housing 162 includes a bottom wall 1621, a top wall 1622 opposite to the bottom wall 1621, and two side walls 1623 connecting the top wall 1622 and the bottom wall 1621. The bottom wall 1621 is provided with a buckle groove 1625 matched with the buckle protrusion 123 of the positioning member 12, and the two side walls 1623 are both provided with a material grabbing port 1626 penetrating through the side wall 1623 and a clamping groove 1628 matched with the buckle block 145 on the printed circuit board 14. The thickness of the rear housing 162 is 0.37mm, and after the printed circuit board 14 is mounted on the rear housing 162, the locking block 145 is locked with the locking groove 1628 to fix the printed circuit board 14 to the metal housing 16, so that the strength of the metal housing 16 is increased. The metal shell 16 is in contact with the printed circuit board 14 to achieve grounding, so as to achieve an EMI protection effect. In the front-rear direction, the material catching ports 1626 are aligned with the first conductive sheet 141 and located on the left and right sides of the printed circuit board 14, and the insulating inner mold 15 can prevent a short circuit between the metal shell 16 and the first conductive sheet 141.

As shown in fig. 7, the grounding plate 31 is connected between the cable 2 and the printed circuit board 14, and includes a locking portion 311 fixedly connected to the cable 2, a pair of grounding claws 312 electrically connected to the two third conductive plates 143 on the printed circuit board 14, a bridging section 313 connected between the pair of grounding claws 312, and a connecting section 314 connected between the locking portion 311 and the bridging section 313. A gap exists between the bridge section 313 and the printed circuit board 14, and the lead 21 soldered to the upper surface of the printed circuit board 14 passes through the gap and is soldered to the second conductive sheet 142. The grounding claws 312 of the grounding strip 31 are electrically connected with the printed circuit board 14, so that the EMI protection effect is improved. In the embodiment disclosed in the present application, the fastening portion 311 is designed as a fastening ring, and in other implementations, other structures may be used to replace the fastening ring to achieve the purpose of fixedly connecting the grounding plate 31 and the cable 2; in other embodiments, the bridging section 313 may not be disposed between the pair of grounding claws 312, and two connecting sections 314 may be disposed to be respectively connected between the fastening part 311 and each grounding claw 312, and of course, the structure is not limited to this, as long as the pair of grounding claws 312 can be connected with the fastening part 311.

As shown in fig. 6, the conductive plastic 32 includes a front conductive portion 321 and a rear conductive portion 322 extending rearward from the front conductive portion 321. The conductive plastic 32 covers the rear housing 162 of the metal housing 16, the positioning element 12, the insulating inner mold 15, the printed circuit board 14 and a part of the grounding strip 31, and the fastening portion 311 of the grounding strip 31 is not covered in the conductive plastic 32. The outer dimension of the front conductive portion 321 is larger than the outer dimension of the rear conductive portion 322. The central line of the front conductive portion 321 coincides with the central line of the rear conductive portion 322, and the area of the longitudinal section of the front conductive portion 321 perpendicular to the central line is larger than the area of the longitudinal section of the rear conductive portion 322 perpendicular to the central line, so that the front conductive portion 321 and the rear conductive portion 322 are stepped. In other embodiments, the grounding plate 31 may be completely encapsulated within the conductive plastic 32.

Referring to fig. 4, the contour of the metal shell 33 matches the contour of the conductive plastic 32, and the metal shell 33 includes a front shell 331 and a rear shell 332 extending backward from the front shell 331, in a length direction, the size of the metal shell 33 is larger than that of the conductive plastic 32, and the metal shell 33 covers the conductive plastic 32 and the fastening portion 311 of the grounding plate 31 exposed outside the conductive plastic 32.

The insulating module 34 covers the rear shell 332 of the metal shell 33, and after the insulating module 34 covers the rear shell 332, the outer contour of the insulating module 34 is flush with the outer contour of the front shell 331. The housing 35 is sleeved on the peripheries of the insulating module 34 and the metal shell 33, and completely covers the insulating module 34 and the metal shell 33.

The metal shell 33 covers the conductive plastic 32 and the buckling part 311 of the grounding strip 31 exposed outside the conductive plastic 32, the conductive plastic 32 covers the rear shell 162 and part of the metal shell 16 of the grounding strip 31, the rear shell 162 of the metal shell 16, the rear conductive part 322 of the conductive plastic 32 and the buckling part 311 of the grounding strip 31 are electrically connected with each other, so that the shielding protection of the cable 2 and the electric connector 1 is realized.

Referring to fig. 1 to 9, when the cable connector assembly (100) of the present invention is assembled, firstly, the conductive terminals 13 are mounted on the insulation body 11 and the positioning member 12, then the welding portions 134 of the conductive terminals 13 are welded to the first conductive sheets 141 on the printed circuit board 14, after the welding is completed, the metal shell 16 is assembled on the insulation body 11, and then the insulation inner mold 15 is injection molded to cover the first welding area of the printed circuit board 14, in the injection molding process, the plastic of the insulation inner mold 15 fills the material catching ports 1626 on two side walls 1623 of the metal shell 16, so as to increase the bonding strength between the insulation inner mold 15 and the metal shell 16; then, the wires 21 of the cable 2 and the grounding claws 312 of the grounding strip 31 are respectively welded to the second conductive strip 142 and the third conductive strip 143, so that the grounding strip 31 is electrically connected with the printed circuit board 14, and the shielding protection effect of the wires 21 of the cable 2 is improved; next, the conductive plastic 32 is injection molded to cover the rear shell 162, the positioning member 12, the insulating inner mold 15, the printed circuit board 14 and a part of the grounding sheet 31 of the metal shell 16, the conductive plastic 32 is fully contacted with the metal shell 16, the grounding sheet 31 and the printed circuit board 14, and in the injection molding process, the material of the conductive plastic 32 fills the material grabbing ports 1626 on two side walls 1623 of the metal shell 16, so as to increase the bonding strength between the conductive plastic 32 and the metal shell 16; then, the metal shell 33 is sleeved on the conductive plastic 32, the insulating module 34 is assembled on the metal shell 33, and finally the housing 35 is sleeved on the metal shell 33 and the insulating module 34. After the assembly is completed, the conductive plastic 32 covers the rear shell 162 of the metal shell 16 and a part of the grounding plate 31, and the metal shell 33 covers the conductive plastic 32 and the fastening portion 311 of the grounding plate 31 exposed outside the conductive plastic 32. The rear shell 162 of the metal shell 16, the rear shell 332 of the metal shell 33, the rear conductive part 322 of the conductive plastic 32, and the buckling part 311 of the grounding plate 31 are electrically connected to each other, so as to shield and protect the cable 2 and the electrical connector 1.

The terms "connect", "install", "fix", and the like in the description of the present invention may be directly connected, installed, and fixed, or indirectly connected, installed, and fixed, that is, allowing a third party to intervene, unless otherwise specified. The terms "first," "second," and "third" may be used herein to describe various elements, but these elements are not limited by these terms, which are used merely to distinguish the described objects, not in any sequential or technical sense.

It should be noted that in the description of the present invention, the terms "lateral", "longitudinal", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the referred device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

The above embodiments are only used for illustrating the present invention and not for limiting the technical solutions described in the present invention, and the understanding of the present specification should be based on the technical personnel in the technical field, such as the directional descriptions of "front", "back", "left", "right", "upper", "lower", etc., although the present specification has described the present invention in detail with reference to the above embodiments, the ordinary skilled in the art should understand that the technical personnel in the technical field can still make modifications or equivalent substitutions on the present invention, and all the technical solutions and modifications thereof without departing from the spirit and scope of the present invention should be covered in the claims of the present invention.