The present invention generally relates to a cable connector assembly, and more particularly to a cable connector assembly capable of simplifying a cable grounding mode.
With reference to
However, a cable grounding mode of the cable connector assembly 100′ needs to organize a bundle of conductors of the shielding layer 33′ into the grounding portion 331′ in addition, and the grounding portions 331′ of the shielding layers 33′ of the plurality of the cables 3′ are connected with the plurality of the grounding pads 42′ of the circuit board 4′ to achieve a grounding effect. The cable grounding mode of the cable connector assembly 100′ not only has a complicated manufacturing process, but also requires more soldering space, thereby a quantity of signal lines that can be used to the circuit board 4′ is affected, specifically, only five 28 AWG cables can be connected to the circuit board 4′. Moreover, in this cable grounding mode, a part of the inner insulating layer 32′ of each cable 3′ is exposed outside without being shielded, and each cable 3′ is easily interfered.
Therefore, it is necessary to provide an innovative cable connector assembly that is capable of simplifying a cable grounding mode, thereby steps of a manufacturing process and a cost consumption of the innovative cable connector assembly are decreased, and a space utilization rate of the circuit board is increased.
An object of the present invention is to provide a cable connector assembly. The cable connector assembly includes a circuit board, a plurality of grounding elements and a plurality of cables. Rear ends of an upper surface and a lower surface of the circuit board are equipped with a plurality of contact pads, and a plurality of grounding pads near to the plurality of the contact pads. The plurality of grounding elements are soldered to the plurality of the grounding pads of the circuit board. Two sides of each grounding element have two clamping portions protruded upward. The plurality of the cables are fastened on the circuit board. Each cable includes an inner conductor, an inner insulating layer, a shielding layer and an outer insulating layer arranged in an inside-to-outside direction and in sequence. The inner conductors of the plurality of the cables are electrically connected with the plurality of the contact pads of the circuit board, at the moment, the shielding layer of each cable is mounted in one grounding element. The shielding layer of each cable is clamped between the two clamping portions of the one grounding element, and the shielding layer of each cable is in contact with the two clamping portions of the one grounding element.
Another object of the present invention is to provide a cable connector assembly. The cable connector assembly includes a circuit board, a plurality of grounding elements and a plurality of cables. Rear ends of an upper surface and a lower surface of the circuit board are equipped with a plurality of contact pads, and a plurality of grounding pads near to the plurality of the contact pads. The plurality of the grounding pads are arranged in two rows and along a front-to-rear direction, and the plurality of the contact pads are arranged in two rows and along the front-to-rear direction. The plurality of the contact pads are corresponding to the plurality of the grounding pads. The contact pads in each row are arranged transversely, and the grounding pads in each row are arranged transversely. One row of the grounding pads is located behind the two rows of the contact pads, the other row of the grounding pads is located between the two rows of the contact pads. The plurality of the grounding elements are soldered to the plurality of the grounding pads of the circuit board. Each grounding element has a base portion, and two clamping portions extended upward from two opposite sides of the base portion. The base portion of each grounding element is soldered to one grounding pad of the circuit board. The two clamping portions include two extending arms extended upward from the two opposite sides of the base portion. Upper portions of the two extending arms are arched inwardly and towards each other to form two clamping blocks, respectively. The plurality of the cables are fastened on the circuit board and arranged in two rows along the front-to-rear direction. Each cable includes an inner conductor, an inner insulating layer, a shielding layer and an outer insulating layer arranged in an inside-to-outside direction and in sequence. The inner conductors of the plurality of the cables are electrically connected with the plurality of the contact pads of the circuit board, at the moment, the shielding layer of each cable is mounted in one grounding element, the shielding layer of each cable is clamped between the two clamping portions of the one grounding element, and the shielding layer of each cable is in contact with the two clamping portions of the one grounding element, the two clamping blocks of each grounding element abut against the shielding layer of one cable.
An object of the present invention is to provide a cable connector assembly. The cable connector assembly includes a body, a circuit board, a plurality of grounding elements and a plurality of cables. The circuit board is accommodated in the body. A rear end of at least one surface of the circuit board is equipped with a plurality of contact pads, and a plurality of grounding pads near to the plurality of the contact pads. The plurality of the grounding pads are arranged in two rows and along a front-to-rear direction, and the plurality of the contact pads are arranged in two rows and along the front-to-rear direction. The plurality of the contact pads are corresponding to the plurality of the grounding pads. The contact pads in each row are arranged transversely, and the grounding pads in each row are arranged transversely. One row of the grounding pads is located behind the two rows of the contact pads, the other row of the grounding pads is located between the two rows of the contact pads. The plurality of the grounding elements are accommodated in the body. The plurality of the grounding elements are soldered to the plurality of the grounding pads of the circuit board. Two sides of each grounding element have two clamping portions protruded upward. The plurality of the cables are soldered to the circuit board. The plurality of the cables are received in the body. Each cable includes an inner conductor, an inner insulating layer, a shielding layer and an outer insulating layer arranged in an inside-to-outside direction and in sequence. The inner conductors of the plurality of the cables are electrically connected with the plurality of the contact pads of the circuit board, the shielding layer of each cable is mounted in one grounding element, the shielding layer of each cable is clamped between the two clamping portions of the one grounding element, the shielding layer of each cable is soldered with the one grounding element, and the shielding layer of each cable is in contact with the two clamping portions of the one grounding element.
As described above, the cable connector assembly reaches a grounding effect by virtue of the plurality of the grounding elements being soldered to the plurality of the grounding pads of the circuit board and directly contacting with the shielding layers of the plurality of the cables to be conductive, so the shielding layers of the plurality of the cables have no need of being deliberately arranged into a bundle in addition, and a manufacturing procedure of the cable connector assembly is simpler, and simultaneously, the cable connector assembly simplifies a cable grounding mode. Furthermore, each grounding element is located under the shielding layer of the one cable, so a required space of each cable on the circuit board is reduced, and a space utilization rate of the circuit board is increased correspondingly.
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 body 1 has a front end 11, and a rear end 12 opposite to the front end 11. When the docking connector 200 is assembled with the body 1 of the cable connector assembly 100, the front end 11 of the body 1 is adapted for being cooperated with the docking connector 200. The rear end 12 of the body 1 is connected to a plurality of cables 3. The body 1 includes a lower cover 15, and an upper cover 16 covered to the lower cover 15. The upper cover 16 of the body 1 has two side walls 13 and a top wall 14. The two side walls 13 are vertically positioned opposite to each other. The top wall 14 is connected between tops of the two side walls 13. Two outer side surfaces of the body 1 are recessed inward to form two sliding grooves 131 penetrating through a rear surface of the body 1. Two outer surfaces of the two side walls 13 of the body 1 are recessed inward to form two first sliding grooves 132 penetrating through bottoms and rears of the two outer surfaces of the two side walls 13 of the body 1. Two outer side surfaces of the lower cover 15 are recessed inward to form two second sliding grooves 133 corresponding to the two first sliding grooves 132, respectively. The two first sliding grooves 132 and the two second sliding grooves 133 are combined to form the two sliding grooves 131.
The unlocking mechanism 2 has two driving arms 21 positioned vertically and opposite to each other. The two driving arms 21 are able to slide frontward and rearward along two sides of the body 1. The two driving arms 21 are received in the two sliding grooves 131 of the body 1, respectively, and the two driving arms 21 are able to slide in the two sliding grooves 131. Rears of top edges of the two driving arms 21 protrude upward, and then are bent towards each other to form a connecting arm 22. The connecting arm 22 is formed between tops of two rear ends of the two driving arms 21.
Rear edges of the two rear ends of the two driving arms 21 are connected with an operating portion 23 protruded outward. The operating portion 23 is of a U shape from a vertical view. A mouth of the U-shaped operating portion 23 faces frontward. A rear end of the operating portion 23 is far away from the connecting arm 22. Specifically, the rear edges of the two rear ends of the two driving arms 21 protrude rearward and then are bent towards each other to form the operating portion 23. Front edges of two free ends of the two driving arms 21 protrude forward to form two unlocking portions 24. Middles of the two unlocking portions 24 are arched oppositely to form two buckling portions 241. The two buckling portions 241 are used to abut against elastic pieces (not shown) of the docking connector 200 to realize that the two buckling portions 241 of the cable connector assembly 100 is locked with and cooperated with the docking connector 200.
The two driving arms 21 and the two unlocking portions 24 are mounted in the two sliding grooves 131. When the unlocking mechanism 2 is in an initial position, the two driving arms 21 are made to slide to unlocking positions by virtue of exerting an outward force on the operating portion 23, at the moment, the two buckling portions 241 of the two driving arms 21 are able to push away the elastic pieces of the docking connector 200 along an outward and rearward direction, so that the body 1 of the cable connector assembly 100 is able to be withdrawn from the docking connector 200.
With reference to
The plurality of the contact pads 41 are corresponding to the plurality of the grounding pads 42. The contact pads 41 in each row are arranged transversely, and the grounding pads 42 in each row are arranged transversely. Each grounding pad 42 is located around one contact pad 41. One row of the grounding pads 42 is located behind the two rows of the contact pads 41. The other row of the grounding pads 42 is located between the two rows of the contact pads 41. Preferably, one contact pad 41 of one row of the contact pads 41, one grounding pad 42 of the one row of the grounding pads 42, one contact pad 41 of the other row of the contact pads 41 and one grounding pad 42 of the other row of the grounding pads 42 are longitudinally arranged in one line and in sequence. Each line of the one contact pad 41 of the one row of the contact pads 41, the one grounding pad 42 of the one row of the grounding pads 42, the one contact pad 41 of the other row of the contact pads 41 and the one grounding pad 42 of the other row of the grounding pads 42 are in alignment with one another.
With reference to
The plurality of the grounding elements 5 are soldered to the plurality of the grounding pads 42 of the circuit board 4 by a SMT (Surface Mounted Technology) procedure. Two sides of each grounding element 5 have two clamping portions 51 protruded upward. Specifically, each grounding element 5 has a base portion 50, and the two clamping portions 51 extended upward from two opposite sides of the base portion 50. The base portion 50 of each grounding element 5 is soldered to one grounding pad 42 of the circuit board 4. The two clamping portions 51 include two extending arms 511 extended upward from the two opposite sides of the base portion 50, and the two extending arms 511 are opposite to each other. Upper portions of the two extending arms 511 are arched inwardly and towards each other to form two clamping blocks 512, respectively. The two clamping blocks 512 face to each other. The two clamping blocks 512 of each grounding element 5 abut against the shielding layer 33 of one cable 3. The upper surface and the lower surface of the circuit board 4 are soldered with the plurality of the grounding elements 5.
The plurality of the cables 3 are soldered to the circuit board 4. The plurality of the cables 3 are received in the body 1 and rear ends of the plurality of the cables 3 are exposed out of the body 1. Each cable 3 is a coaxial cable. Each cable 3 includes an inner conductor 31, an inner insulating layer 32, a shielding layer 33, and an outer insulating layer 34 arranged in an inside-to-outside direction and in sequence. The shielding layer 33 is a mesh-shaped conductor. The shielding layer 33 of each cable 3 is earthed to make external interference signals to be introduced into a ground through the shielding layer 33 so as to prevent the interference signals from entering the inner conductor 31 of each cable 3 and further reduce losses of transmission signals of each cable 3.
The inner conductors 31 of the plurality of the cables 3 are electrically connected with the plurality of the contact pads 41 of the circuit board 4, at the moment, the shielding layer 33 of each cable 3 is mounted downward in one grounding element 5. The shielding layer 33 of each cable 3 is soldered with the one grounding element 5. The shielding layer 33 of each cable 3 is clamped between the two clamping portions 51 of the one grounding element 5, and the shielding layer 33 of each cable 3 is in contact with the two clamping portions 51 of the one grounding element 5, in this way, the shielding layer 33 of each cable 3 of the cable connector assembly 100 reaches a grounding effect by virtue of the two clamping portions 51 of the one grounding element 5 contacting with the shielding layer 33 of each cable 3. Each grounding element 5 is located under the shielding layer 33 of the one cable 3, so a required space of each cable 3 on the circuit board 4 is reduced, and then a space utilization rate of the circuit board 4 is increased. The plurality of the cables 3 are fastened on the circuit board 4 and are arranged in two rows along the front-to-rear direction.
Because the contact pads 41 of the first group and the contact pads 41 of the second group are staggered along the front-to-rear direction, and the grounding pads 42 of the first group and the grounding pads 42 of the second group are staggered along the front-to-rear direction, the plurality of the cables 3 are arranged in a first row and a second row. The cables 3 of the first row and the cables 3 of the second row are staggered. Each two adjacent cables 3 in the first row are spaced from each other to form a gap 301 therebetween. The gaps 301 among the cables 3 of the first row are transversely distributed from one side of the cables 3 of the first row to the other side of the cables 3 of the first row. An area closest to the cable 3 located at an outermost position of the other side of the cables 3 of the first row is also defined as the gap 301. The cables 3 of the second row are positioned in the gaps 301 of each two adjacent cables 3 in the first row and the area closest to the cable 3 located at the outermost position of the other side of the cables 3 of the first row.
Specifically, in this preferred embodiment, the plurality of the cables 3 are eight 28AWG cables 3 connected to the circuit board 4. Compare the cable connector assembly 100 with the cable connector assembly 100′ in prior art, the circuit board 4 is connected with more cables 3, so that the cable connector assembly 100 reaches a better transmission effect under a condition of a usage space of the circuit board 4 of the cable connector assembly 100 and a usage space of the circuit board 4′ of the cable connector assembly 100′ being the same.
As described above, the cable connector assembly 100 reaches the grounding effect by virtue of the plurality of the grounding elements 5 being soldered to the plurality of the grounding pads 42 of the circuit board 4 and directly contacting with the shielding layers 33 of the plurality of the cables 3 to be conductive, so the shielding layers 33 of the plurality of the cables 3 have no need of being deliberately arranged into a bundle in addition, and a manufacturing procedure of the cable connector assembly 100 is simpler, and simultaneously, the cable connector assembly 100 simplifies a cable grounding mode. Furthermore, each grounding element 5 is located under the shielding layer 33 of the one cable 3, so the required space of each cable 3 on the circuit board 4 is reduced, and the space utilization rate of the circuit board 4 is increased correspondingly.