The present application is based on, and claims priority from, China Patent Application No. 202221483292.5, filed Jun. 14, 2022, the disclosure of which is hereby incorporated by reference herein in its entirety.
The present invention generally relates to an electrical connector, and more particularly to an electrical connector improving a high-frequency signal transmission.
In various connector types which are frequently used by various electronic products, universal serial bus (USB) connectors are the most widely applied. With the improvement of sciences and technologies, kinds of the universal serial bus connectors are more and more, such as USB 2.0, USB 3.0, Micro USB, Mini USB or USB TYPE-C. The USB TYPE-C connectors have been widely applied in the various electronic products. The USB TYPE-C connectors have already reached a 40 Gbps transmission specification.
When high-frequency signals are transmitted, an internal structure of an electrical connector makes an electromagnetic field and generates a resonance, a high-frequency characteristic is particularly poor in a certain frequency band, and an impedance is mismatched, so an insertion loss and a return loss of the signals become worse to affect crosstalk results. When the high-frequency signals are transmitted, the above-mentioned phenomenon will be more serious, so that signal transmission quality of the electrical connector is further affected.
Thus, it is essential to provide an innovative electrical connector improving a high-frequency signal transmission.
An object of the present invention is to provide an electrical connector. The electrical connector includes an insulating housing, an upper terminal assembly, a center grounding plate and an outer shell. A rear end of the insulating housing has two first penetrating grooves vertically penetrating through the insulating housing. The upper terminal assembly is fastened in the insulating housing. The upper terminal assembly includes a plurality of upper terminals and an upper base portion. The plurality of the upper terminals are fastened in the upper base portion. The plurality of the upper terminals include a plurality of upper grounding terminals and a plurality of upper signal terminals. Two adjacent upper signal terminals of each side of the upper terminal assembly are disposed between two upper grounding terminals. Each upper terminal has an upper fastening portion. A front end of the upper fastening portion extends frontward to form an upper contacting portion. A rear end of the upper fastening portion is bent upward to form a first upper bending portion. An upper end of the first upper bending portion extends rearward to form an upper extending portion. A rear end of the upper extending portion is bent downward to form a second upper bending portion. A lower end of the second upper bending portion extends rearward to form an upper soldering portion. A rear end of the upper base portion defines two second penetrating grooves vertically penetrating through the upper base portion. The two second penetrating grooves are aligned with the two first penetrating grooves along a vertical direction. The upper extending portions of two outermost upper grounding terminals of the plurality of the upper terminals are exposed outside to a top surface of the upper base portion through the two second penetrating grooves. The upper extending portions of the two outermost upper grounding terminals of the plurality of the upper terminals are exposed outside of the insulating housing through the two second penetrating grooves and the two first penetrating grooves. The center grounding plate is fastened in the insulating housing. The center grounding plate has a front plate. The front plate is corresponding to the upper fastening portions and the upper contacting portions of the plurality of the upper terminals. A rear end of the front plate is bent upward to form a bending plate. The bending plate is corresponding to the first upper bending portions of the plurality of the upper terminals. A rear end of the bending plate extends rearward to form a rear plate. The rear plate is corresponding to the upper extending portions of the plurality of the upper terminals of the upper terminal assembly. Two opposite sides of a top surface of the rear plate protrude towards the upper grounding terminal to form two protrusions, respectively. The upper extending portions of the two outermost upper grounding terminals of the upper terminal assembly contact with the two protrusions to define a lower grounding point. The outer shell is disposed to a top surface of the insulating housing. Two opposite sides of a rear end of a top surface of the outer shell extend towards the insulating housing to form two elastic arms, respectively. The two elastic arms pass through the two first penetrating grooves and the two second penetrating grooves, and then the two elastic arms contact with the upper extending portions of the two outermost upper grounding terminals of the upper terminal assembly to define an upper grounding point. The upper grounding point is aligned with the lower grounding point along the vertical direction.
Another object of the present invention is to provide an electrical connector. The electrical connector includes an insulating housing, an upper terminal assembly, a center grounding plate, a lower terminal assembly and an outer shell. A rear end of the insulating housing has two first penetrating grooves vertically penetrating through the insulating housing. The upper terminal assembly is fastened in the insulating housing. The upper terminal assembly includes a plurality of upper terminals and an upper base portion. The plurality of the upper terminals are fastened in the upper base portion. The plurality of the upper terminals include a plurality of upper grounding terminals and a plurality of upper signal terminals. Two adjacent upper signal terminals of each side of the upper terminal assembly are disposed between two upper grounding terminals. Each upper terminal has an upper fastening portion. A front end of the upper fastening portion extends frontward to form an upper contacting portion. A rear end of the upper fastening portion is bent upward to form a first upper bending portion. An upper end of the first upper bending portion extends rearward to form an upper extending portion. A rear end of the upper extending portion is bent downward to form a second upper bending portion. A lower end of the second upper bending portion extends rearward to form an upper soldering portion. A rear end of the upper base portion defines two second penetrating grooves vertically penetrating through the upper base portion. The two second penetrating grooves are aligned with the two first penetrating grooves along a vertical direction. The upper extending portions of two outermost upper grounding terminals of the plurality of the upper terminals are exposed outside to a top surface of the upper base portion through the two second penetrating grooves. The upper extending portions of the two outermost upper grounding terminals of the plurality of the upper terminals are exposed outside of the insulating housing through the two second penetrating grooves and the two first penetrating grooves. One side of the upper fastening portion of each upper signal terminal of two sides of the upper terminal assembly is recessed inward to form a first lacking groove. A junction between one side of the first upper bending portion and one side of the upper extending portion of each upper signal terminal of the two sides of the upper terminal assembly is recessed inward to form a second lacking groove. A junction between one side of the upper fastening portion and one side of the upper contacting portion of each upper grounding terminal is recessed inward to form a third lacking groove. One side of the second upper bending portion of each upper grounding terminal is recessed inward to form a fourth lacking groove extending to the rear end of the upper extending portion. The center grounding plate is fastened in the insulating housing. The center grounding plate has a front plate. The front plate is corresponding to the upper fastening portions and the upper contacting portions of the plurality of the upper terminals. A rear end of the front plate is bent upward to form a bending plate. The bending plate is corresponding to the first upper bending portions of the plurality of the upper terminals. A rear end of the bending plate extends rearward to form a rear plate. The rear plate is corresponding to the upper extending portions of the plurality of the upper terminals of the upper terminal assembly. Two opposite sides of a top surface of the rear plate protrude towards the upper grounding terminal to form two protrusions, respectively. The upper extending portions of the two outermost upper grounding terminals of the upper terminal assembly contact with the two protrusions to define a lower grounding point. The lower terminal assembly is fastened in the insulating housing. The center grounding plate is disposed between the upper terminal assembly and the lower terminal assembly. The lower terminal assembly includes a plurality of lower terminals. The plurality of the lower terminals include a plurality of lower signal terminals. Each lower terminal has a lower fastening portion. One side of the lower fastening portion of each lower signal terminal of two sides of the lower terminal assembly is recessed inward to form a fifth lacking groove. The outer shell is disposed to a top surface of the insulating housing. Two opposite sides of a rear end of a top surface of the outer shell extend towards the insulating housing to form two elastic arms, respectively. The two elastic arms pass through the two first penetrating grooves and the two second penetrating grooves, and then the two elastic arms contact with the upper extending portions of the two outermost upper grounding terminals of the upper terminal assembly to define an upper grounding point. The upper grounding point is aligned with the lower grounding point along the vertical direction.
Another object of the present invention is to provide an electrical connector. The electrical connector includes an insulating housing, an upper terminal assembly, a center grounding plate, a lower terminal assembly and an outer shell. A rear end of the insulating housing has two first penetrating grooves vertically penetrating through the insulating housing. The upper terminal assembly is fastened in the insulating housing. The upper terminal assembly includes a plurality of upper terminals and an upper base portion. The plurality of the upper terminals are fastened in the upper base portion. The plurality of the upper terminals include a plurality of upper grounding terminals and a plurality of upper signal terminals. Two adjacent upper signal terminals of each side of the upper terminal assembly are disposed between two upper grounding terminals. Each upper terminal has an upper fastening portion. A front end of the upper fastening portion extends frontward to form an upper contacting portion. A rear end of the upper fastening portion is bent upward to form a first upper bending portion. An upper end of the first upper bending portion extends rearward to form an upper extending portion. A rear end of the upper extending portion is bent downward to form a second upper bending portion. A lower end of the second upper bending portion extends rearward to form an upper soldering portion. A rear end of the upper base portion defines two second penetrating grooves vertically penetrating through the upper base portion. The two second penetrating grooves are aligned with the two first penetrating grooves along a vertical direction. The upper extending portions of two outermost upper grounding terminals of the plurality of the upper terminals are exposed outside to a top surface of the upper base portion through the two second penetrating grooves. The upper extending portions of the two outermost upper grounding terminals of the plurality of the upper terminals are exposed outside of the insulating housing through the two second penetrating grooves and the two first penetrating grooves. One side of the upper fastening portion of each upper signal terminal of two sides of the upper terminal assembly is recessed inward to form a first lacking groove. A junction between one side of the first upper bending portion and one side of the upper extending portion of each upper signal terminal of the two sides of the upper terminal assembly is recessed inward to form a second lacking groove. A junction between one side of the upper fastening portion and one side of the upper contacting portion of each upper grounding terminal is recessed inward to form a third lacking groove. One side of the second upper bending portion of each upper grounding terminal is recessed inward to form a fourth lacking groove extending to the rear end of the upper extending portion. The center grounding plate is fastened in the insulating housing. The center grounding plate has a front plate. The front plate is corresponding to the upper fastening portion and the upper contacting portion of each upper terminal. A rear end of the front plate is bent upward to form a bending plate. The bending plate is corresponding to the first upper bending portions of the plurality of the upper terminals. A rear end of the bending plate extends rearward to form a rear plate. The rear plate is corresponding to the upper extending portions of the upper terminal assembly. Two opposite sides of a top surface of the rear plate protrude towards the upper grounding terminal to form two protrusions, respectively. Bottom surfaces of the rear parts of the upper extending portions of the two outermost upper grounding terminals of the upper terminal assembly contact with the two protrusions to define a lower grounding point. The lower terminal assembly is fastened in the insulating housing. The center grounding plate is disposed between the upper terminal assembly and the lower terminal assembly. The lower terminal assembly includes a plurality of lower terminals. The plurality of the lower terminals include a plurality of lower signal terminals. Each lower terminal has a lower fastening portion. One side of the lower fastening portion of each lower signal terminal of two sides of the lower terminal assembly is recessed inward to form a fifth lacking groove. The outer shell is disposed to a top surface of the insulating housing. Two opposite sides of a rear end of a top surface of the outer shell extend towards the insulating housing to form two elastic arms, respectively. The two elastic arms pass through the two first penetrating grooves and the two second penetrating grooves, and top surfaces of the rear parts of the upper extending portions of the two outermost upper grounding terminals of the upper terminal assembly contact with the two elastic arms to define an upper grounding point. The upper grounding point is aligned with the lower grounding point along the vertical direction.
As described above, the electrical connector achieves a 40 Gbps specification by virtue of the first lacking groove, the second lacking groove, the third lacking groove, the fourth lacking groove and the fifth lacking groove. Furthermore, the bottom surfaces of the rear parts of the upper extending portions of the two outermost upper grounding terminals of the upper terminal assembly contact with the two protrusions of the center grounding plate, and the top surfaces of the rear parts of the upper extending portions of the two outermost upper grounding terminals of the upper terminal assembly contact with the two elastic arms of the outer shell for improving a resonance problem generated from a grounding loop to an adjacent radio frequency (RF) signal of a high frequency electromagnetic wave in a high-frequency characteristic of a transmission signal of the electrical connector. As a result, the electrical connector improves a high-frequency signal transmission.
The present invention will be apparent to those skilled in the art by reading the following description, with reference to the attached drawings, in which:
With reference to
The terminal assembly 2 is fastened in the insulating housing 1. The center grounding plate 3 is mounted in a middle of the terminal assembly 2, and the terminal assembly 2 and the center grounding plate 3 are fastened in the insulating housing 1. The insulating housing 1 surrounds the center grounding plate 3 and the terminal assembly 2. The two shielding plates 4 are disposed to an upper surface and a lower surface of the insulating housing 1. The inner shell 5 is disposed to a front end of the insulating housing 1, and the insulating housing 1 is partially surrounded by the inner shell 5. The outer shell 6 is disposed to top surfaces of the insulating housing 1 and the inner shell 5.
Referring to
Middles of a top surface and a bottom surface of the base body 11 are recessed inward to form two first concave surfaces 111, respectively. The two first concave surfaces 111 extend to the front surface of the base body 11. The two first concave surfaces 111 are corresponding to corresponding mechanisms of the two shielding plates 4. Two opposite sides of each first concave surface 111 are recessed inward to form two first location holes 112, respectively. The corresponding mechanisms of the two shielding plates 4 are fastened in the first location holes 112 of the base body 11, so that the two shielding plates 4 are located to the insulating housing 1, and the two shielding plates 4 are fastened to the insulating housing 1. Front ends of the top surface and the bottom surface of the base body 11 are recessed inward to form a positioning hole 113. Two sides of the front end of the top surface of the base body 11 are recessed inward to form two positioning holes 113, respectively. Two sides of the front end of the bottom surface of the base body 11 are recessed inward to form another two positioning holes 113, respectively. A corresponding mechanism of the inner shell 5 is fastened in the positioning hole 113, so that the inner shell 5 is located to the insulating housing 1, and the inner shell 5 is fastened to the insulating housing 1.
Two middles of a top surface and a bottom surface of the stepping portion 12 are recessed inward to form two second concave surfaces 121, respectively. The two second concave surfaces 121 are corresponding to two corresponding positions of the two shielding plates 4. Two opposite sides of each second concave surface 121 are recessed inward to form two second location holes 122, respectively. The corresponding positions of the two shielding plates 4 are fastened in the second location holes 122 of the stepping portion 12, so that the two shielding plates 4 are located to the insulating housing 1, and the two shielding plates 4 are fastened to the insulating housing 1.
Referring to
Each upper terminal 211 has an upper fastening portion 2111, an upper contacting portion 2112, a first upper bending portion 2113, an upper extending portion 2114, a second upper bending portion 2115 and an upper soldering portion 2116. A front end of the upper fastening portion 2111 extends frontward to form the upper contacting portion 2112. A rear end of the upper fastening portion 2111 is bent upward to form the first upper bending portion 2113. An upper end of the first upper bending portion 2113 extends rearward to form the upper extending portion 2114. A rear end of the upper extending portion 2114 is bent downward to form the second upper bending portion 2115. A lower end of the second upper bending portion 2115 extends rearward to form the upper soldering portion 2116.
The upper terminal assembly 21 has a plurality of upper grounding terminals 213 and a plurality of upper signal terminals 214. The plurality of the upper terminals 211 include the plurality of the upper grounding terminals 213 and the plurality of the upper signal terminals 214. In the preferred embodiment, two adjacent upper signal terminals 214 of each side of the upper terminal assembly 21 are disposed between two upper grounding terminals 213. One side of the upper fastening portion 2111 of each upper signal terminal 214 of two sides of the upper terminal assembly 21 is recessed inward to form a first lacking groove 215. A junction between one side of the first upper bending portion 2113 and one side of the upper extending portion 2114 of each upper signal terminal 214 of the two sides of the upper terminal assembly 21 is recessed inward to form a second lacking groove 216. Two opposite sides of a front of a bottom surface of the upper contacting portion 2112 of each upper signal terminal 214 of the two sides of the upper terminal assembly 21 slantwise extend inward and downward to form two upper chamfers 217. The first lacking groove 215, the second lacking groove 216 and each upper chamfer 217 are used for improving an impedance of the electrical connector 100. The first lacking grooves 215 of each two adjacent upper signal terminals 214 of the two sides of the upper terminal assembly 21 face each other. The second lacking grooves 216 of each two adjacent upper signal terminals 214 of the two sides of the upper terminal assembly 21 face each other. In the preferred embodiment, a width of each upper grounding terminal 213 is wider than a width of each upper signal terminal 214.
A junction between one side of the upper fastening portion 2111 and one side of the upper contacting portion 2112 of each upper grounding terminal 213 is recessed inward to form a third lacking groove 218. The third lacking groove 218 is used for improving the impedance of the electrical connector 100. One side of the second upper bending portion 2115 of each upper grounding terminal 213 is recessed inward to form a fourth lacking groove 219 extending to the rear end of the upper extending portion 2114.
A first gap 101 is formed between the upper extending portion 2114 of the upper grounding terminal 213 and the upper extending portion 2114 of the upper signal terminal 214 which are adjacent to each other. A second gap 102 is formed between an inner wall of the fourth lacking groove 219 of the upper grounding terminal 213 and the second upper bending portion 2115 of the upper signal terminal 214 which are adjacent to each other. A third gap 103 is formed between an inner wall of the third lacking groove 218 of the upper grounding terminal 213 and the upper contacting portion 2112 of the upper signal terminal 214 which are adjacent to each other. A fourth gap 104 is formed between the upper contacting portions 2112 of the two adjacent upper signal terminals 214 of each side of the upper terminal assembly 21. A fifth gap 105 is formed between two inner walls of the two first lacking grooves 215 of the two adjacent upper signal terminals 214 of each side of the upper terminal assembly 21. A sixth gap 106 is formed between two inner walls of the two second lacking grooves 216 of the two adjacent upper signal terminals 214 of each side of the upper terminal assembly 21. Therefore, the first gap 101 is smaller than the second gap 102. The second gap 102 is equal to the third gap 103. The third gap 103 is equal to the fourth gap 104. The fourth gap 104 is smaller than the fifth gap 105. The fifth gap 105 is equal to the sixth gap 106. The first gap 101, the second gap 102, the third gap 103, the fourth gap 104, the fifth gap 105 and the sixth gap 106 are used for improving the impedance of the electrical connector 100.
The upper base portion 212 has an upper base body 2121, an upper tongue portion 2122, an upper stepping portion 2123 and an upper rear portion 2124. A lower portion of a front surface of the upper base body 2121 extends frontward to form the upper tongue portion 2122. A rear end of the upper base body 2121 is bent upward to form the upper stepping portion 2123. A top end of the upper stepping portion 2123 extends rearward to form the upper rear portion 2124. The upper fastening portions 2111 of the plurality of the upper terminals 211 are fastened in the upper base body 2121. The upper fastening portions 2111 of the plurality of the upper terminals 211 are surrounded by the upper base body 2121. The upper contacting portions 2112 of the plurality of the upper terminals 211 are fastened to the upper tongue portion 2122 of the upper base portion 212. The upper contacting portions 2112 of the plurality of the upper terminals 211 are partially surrounded by the upper tongue portion 2122 of the upper base portion 212. The first upper bending portions 2113 of the plurality of the upper terminals 211 are fastened in the upper stepping portion 2123 of the upper base portion 212. The first upper bending portions 2113 of the plurality of the upper terminals 211 are surrounded by the upper stepping portion 2123 of the upper base portion 212. The upper extending portions 2114 and the second upper bending portions 2115 of the plurality of the upper terminals 211 are fastened in the upper rear portion 2124 of the upper base portion 212. The upper extending portions 2114 and the second upper bending portions 2115 of the plurality of the upper terminals 211 are surrounded by the upper rear portion 2124 of the upper base portion 212. The upper soldering portions 2116 of the plurality of the upper terminals 211 are exposed out of a rear end of the upper rear portion 2124.
The upper base portion 212 has a plurality of upper fastening grooves 2125, an upper receiving groove 2126, two upper protruding blocks 2127 and two second penetrating grooves 2128. The plurality of the upper fastening grooves 2125 are formed to the upper tongue portion 2122 and the upper rear portion 2124 of the upper base portion 212. When the plurality of the upper terminals 211 and the upper base portion 212 are in a molding process, the plurality of the upper fastening grooves 2125 are cooperated with a jig (not shown) to be used for stabilizing positions of the plurality of the upper terminals 211. The plurality of the upper fastening grooves 2125 improve an insertion loss, a return loss and the impedance of the electrical connector 100. A bottom surface of the upper base portion 212 is recessed inward to form the upper receiving groove 2126. The upper receiving groove 2126 is used for receiving a corresponding structure of the lower terminal assembly 22, so that the upper terminal assembly 21 is located to the lower terminal assembly 22, and the upper terminal assembly 21 is fastened to the lower terminal assembly 22.
Two portions of the bottom surface of the upper base portion 212 extend downward to form the two upper protruding blocks 2127. The upper receiving groove 2126 is located between the two upper protruding blocks 2127. The two upper protruding blocks 2127 are used for buckling with the corresponding structure of the lower terminal assembly 22, so that the upper terminal assembly 21 is located to the lower terminal assembly 22, and the upper terminal assembly 21 is fastened to the lower terminal assembly 22. A rear end of the upper base portion 212 defines the two second penetrating grooves 2128 vertically penetrating through the upper base portion 212. Two sides of a rear of the upper rear portion 2124 of the upper base portion 212 define the two second penetrating grooves 2128 penetrating through a top surface and a bottom surface of the upper rear portion 2124 of the upper base portion 212. The two second penetrating grooves 2128 are corresponding to the two first penetrating grooves 15 of the insulating housing 1. The two second penetrating grooves 2128 are aligned with the two first penetrating grooves 15 of the insulating housing 1 along a vertical direction. Rear parts of the upper extending portions 2114 of two outermost upper grounding terminals 213 of the plurality of the upper terminals 211 are exposed outside to a top surface of the upper base portion 212 through the two second penetrating grooves 2128. The rear parts of the upper extending portions 2114 of the two outermost upper grounding terminals 213 of the plurality of the upper terminals 211 are exposed outside of the insulating housing 1 through the two second penetrating grooves 2128 and the two first penetrating grooves 15. The rear parts of the upper extending portions 2114 of the plurality of the upper terminals 211 are exposed outside of the insulating housing 1 through the two second penetrating grooves 2128 and the two first penetrating grooves 15.
The lower terminal assembly 22 includes a plurality of lower terminals 221 and a lower base portion 222. The plurality of the lower terminals 221 are fastened to the lower base portion 222. Each lower terminal 221 has a lower fastening portion 2211, a lower contacting portion 2212, a lower bending portion 2213 and a lower soldering portion 2214. A front end of the lower fastening portion 2211 extends frontward to form the lower contacting portion 2212. A rear end of the lower fastening portion 2211 is bent upward to form the lower bending portion 2213. A top end of the lower bending portion 2213 extends rearward to form the lower soldering portion 2214.
The lower terminal assembly 22 has a plurality of lower grounding terminals 223 and a plurality of lower signal terminals 224. The plurality of the lower terminals 221 include the plurality of the lower grounding terminals 223 and the plurality of the lower signal terminals 224. In the preferred embodiment, two adjacent lower signal terminals 224 of each side of the lower terminal assembly 22 are disposed between two lower grounding terminals 223. One side of the lower fastening portion 2211 of each lower signal terminal 224 of two sides of the lower terminal assembly 22 is recessed inward to form a fifth lacking groove 225. Two opposite sides of a front of a top surface of the lower contacting portion 2212 of each lower signal terminal 224 of the two sides of the lower terminal assembly 22 slantwise extend inward and upward to form two lower chamfers 226. The fifth lacking groove 225 and the two lower chamfers 226 of each lower signal terminal 224 of the two sides of the lower terminal assembly 22 are used for improving the impedance of the electrical connector 100. In the preferred embodiment, a clearance 107 is formed between two facing inner walls of the two fifth lacking grooves 225 of the two adjacent lower signal terminals 224 of each side of the lower terminal assembly 22. A function of the clearance 107 is the same as a function of the fifth gap 105. A structure of the clearance 107 is the same as a structure of the fifth gap 105. The clearance 107 is equal to the fifth gap 105.
The lower base portion 222 has a lower base body 2221, a lower tongue portion 2222, a lower stepping portion 2223 and a lower rear portion 2224. A front end of the lower base body 2221 extends frontward to form the lower tongue portion 2222. A rear end of the lower base body 2221 is bent upward to form the lower stepping portion 2223. A top end of the lower stepping portion 2223 extends rearward to form the lower rear portion 2224. The lower fastening portions 2211 of the plurality of the lower terminals 221 are fastened in the lower base body 2221 of the lower base portion 222. The lower fastening portions 2211 of the plurality of the lower terminals 221 are surrounded by the lower base body 2221 of the lower base portion 222. The lower contacting portions 2212 of the plurality of the lower terminals 221 are fastened to the lower tongue portion 2222 of the lower base portion 222. The lower contacting portions 2212 of the plurality of the lower terminals 221 are partially surrounded by the lower tongue portion 2222 of the lower base portion 222. The lower bending portions 2213 of the plurality of the lower terminals 221 are fastened in the lower stepping portion 2223 of the lower base portion 222. The lower bending portions 2213 of the plurality of the lower terminals 221 are surrounded by the lower stepping portion 2223 of the lower base portion 222. The lower soldering portions 2214 of the plurality of the lower terminals 221 are fastened to the lower rear portion 2224. Front ends of the lower soldering portions 2214 of the plurality of the lower terminals 221 are surrounded by the lower rear portion 2224. Rear ends of the lower soldering portions 2214 of the plurality of the lower terminals 221 are exposed out of a rear end of the lower rear portion 2224 of the lower base portion 222.
The lower base portion 222 has a plurality of lower fastening grooves 2225, two lower receiving grooves 2226 and a lower protruding block 2227. The plurality of the lower fastening grooves 2225 are formed to the lower base body 2221, the lower tongue portion 2222 and the lower rear portion 2224. When the plurality of the lower terminals 221 and the lower base portion 222 are in a molding process, the plurality of the lower fastening grooves 2225 are cooperated with the jig (not shown) to be used for stabilizing positions of the plurality of the lower terminals 221. The plurality of the lower fastening grooves 2225 improve the insertion loss, the return loss and the impedance of the electrical connector 100. Two portions of a top surface of the lower base portion 222 are recessed inward to form the two lower receiving grooves 2226. The two upper protruding blocks 2127 of the upper terminal assembly 21 are received in the two lower receiving grooves 2226, so that the upper terminal assembly 21 is located to the lower terminal assembly 22, and the upper terminal assembly 21 is fastened to the lower terminal assembly 22. The top surface of the lower base portion 222 extends upward to form the lower protruding block 2227. In the preferred embodiment, the lower protruding block 2227 is disposed between the two lower receiving grooves 2226. The lower protruding block 2227 is buckled in the upper receiving groove 2126 of the upper terminal assembly 21, so that the upper terminal assembly 21 is located to the lower terminal assembly 22, and the upper terminal assembly 21 is fixed to the lower terminal assembly 22. The lower protruding block 2227 is disposed between the two upper protruding blocks 2127 of the upper base portion 212.
Referring to
The front plate 31 has a third location hole 311 penetrating through a top surface and a bottom surface of the front plate 31. The two upper protruding blocks 2127 of the upper terminal assembly 21 are fastened in the third location hole 311 of the front plate 31, so that the center grounding plate 3 is located to the upper terminal assembly 21, and the center grounding plate 3 is fastened to the upper terminal assembly 21. The lower protruding block 2227 of the lower terminal assembly 22 is fastened in the third location hole 311 of the front plate 31, so that the center grounding plate 3 is located to the lower terminal assembly 22, and the center grounding plate 3 is fastened to the lower terminal assembly 22. Two opposite sides of the rear end of the front plate 31 extend outward to form two wings 312. The two wings 312 are exposed outside of two opposite sides of the base body 11 of the insulating housing 1. The two wings 312 contact with two opposite sides of an inner surface of the inner shell 5.
Referring to
In the preferred embodiment, the rear plate 33 is corresponding to the upper extending portions 2114 of the plurality of the upper terminals 211 of the upper terminal assembly 21. A length of the rear plate 33 is longer than a length of the lower soldering portion 2214 of each lower terminal 221 of the lower terminal assembly 22. The rear plate 33 is corresponding to positions of the fourth lacking grooves 219 extending to the rear ends of the upper extending portions 2114 of the plurality of the upper grounding terminals 213.
Referring to
Two opposite sides of the front fastening plate 41 extend towards the insulating housing 1 to form the first buckling portion 44 and the U-shaped restricting portion 45, respectively. In the preferred embodiment, the first buckling portion 44 is a T shape. The restricting portion 45 is the U shape. The first buckling portions 44 and the restricting portions 45 of the two shielding plates 4 are buckled with each other to fasten the two shielding plates 4. The first buckling portions 44 and the restricting portions 45 are disposed in the two second location holes 122 of the stepping portion 12 of the insulating housing 1, so that the two shielding plates 4 are located to the insulating housing 1, and the two shielding plates 4 are fastened to the insulating housing 1. Two opposite sides of the rear fastening plate 43 extend towards the insulating housing 1 to form two second buckling portions 46. The second buckling portions 46 of the two shielding plates 4 are disposed in the two first location holes 112 of the base body 11 of the insulating housing 1, so that the two shielding plates 4 are located to the insulating housing 1, and the two shielding plates 4 are fastened to the insulating housing 1. Two outer surfaces of the two rear fastening plates 43 of the two shielding plates 4 contact with the inner surface of the inner shell 5.
Referring to
Referring to
In the preferred embodiment, the rear parts of the upper extending portions 2114 of the two outermost upper grounding terminals 213 of the upper terminal assembly 21 define a grounding area 90. In the concrete implementation, the grounding area 90 is without being limited to be defined at the rear parts of the upper extending portions 2114 of the two outermost upper grounding terminals 213 of the upper terminal assembly 21. The two protrusions 331 of the center grounding plate 3 contact with a bottom surface of the grounding area 90 to define a lower grounding point 92. The two elastic arms 61 of the outer shell 6 contact with a top surface of the grounding area 90 to define the upper grounding point 91. Furthermore, the bottom surfaces of the rear parts of the upper extending portions 2114 of the two outermost upper grounding terminals 213 of the upper terminal assembly 21 contact with the two protrusions 331 of the center grounding plate 3 to define the lower grounding point 92. The top surfaces of the rear parts of the upper extending portions 2114 of the two outermost upper grounding terminals 213 of the upper terminal assembly 21 contact with the two elastic arms 61 of the outer shell 6 to define the upper grounding point 91. The upper grounding point 91 is aligned with the lower grounding point 92 along the vertical direction. The upper grounding point 91 is opposite to the lower grounding point 92 along the vertical direction. Therefore, a shortest grounding path is formed among the two elastic arms 61 of the outer shell 6, the upper grounding point 91, the rear parts of the upper extending portions 2114 of the two outermost upper grounding terminals 213, the lower grounding point 92 and the two protrusions 331 of the center grounding plate 3.
As described above, the electrical connector 100 achieves a 40 Gbps specification by virtue of the first lacking groove 215, the second lacking groove 216, the third lacking groove 218, the fourth lacking groove 219 and the fifth lacking groove 225. Furthermore, the bottom surfaces of the rear parts of the upper extending portions 2114 of the two outermost upper grounding terminals 213 of the upper terminal assembly 21 contact with the two protrusions 331 of the center grounding plate 3, and the top surfaces of the rear parts of the upper extending portions 2114 of the two outermost upper grounding terminals 213 of the upper terminal assembly 21 contact with the two elastic arms 61 of the outer shell 6 for improving the resonance problem generated from the grounding loop to the adjacent radio frequency (RF) signal of the high frequency electromagnetic wave in the high-frequency characteristic of the transmission signal of the electrical connector 100. As a result, the electrical connector 100 improves a high-frequency signal transmission.
Number | Date | Country | Kind |
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202221483292.5 | Jun 2022 | CN | national |