JP3159012U - Electrical connector - Google Patents

Abstract

An electrical connector using an electronic device is provided. According to the contact arrangement, the two signal contacts of the signal differential pairs 106a and 106b of the first terminal arrangement are closely adjacent to each other, and the power supply contact and the ground contact are not separated from each other. In the contact arrangement, the signal differential pair is not separated by the power contact and the ground contact. First, the effect of signal differential pairs and other contacts transmitting signals is minimized. That is, crosstalk can be reduced in high-speed and high-frequency transmission of the first terminal array. [Selection] Figure 4

Description

  The present invention relates to an electrical connector using an electronic device.

  Regarding the development and improvement of the transmission interface of the wiring of the electronic device, generally, each contact of the wiring increases with the transmission speed and frequency. Therefore, it is very important for the contact of the electrical connector to reduce cross talk by high speed and high frequency transmission.

However, the above electrical connector has the following drawbacks.
Each contact of the conventional wiring increases with the transmission speed and frequency, and adopts an array side by side. However, crosstalk occurs in electrical connector contacts due to transmission at high speed and high frequency.

  An object of the present invention is to provide an electrical connector using an electronic device.

  The electrical connector of the present invention includes a metal case, an insulating base, and a contact arrangement. The metal case is coated on the outside of the insulating base having the contact arrangement. The metal case can avoid radio interference when grounding the outside. The electrical connector is divided into two types of contact arrangements, and other species are extended from the seed contact arrangement. And the terminal of the said electrical connector will be covered, if it connects with a signal cable. The first terminal arrangement includes two pairs of differential pair contacts and a ground contact. The signal contact is a pair of signal differential pairs, and the signal contact is another pair of signal differential pairs. The arrangement of the second terminals includes a pair of signal differential pairs, a ground contact, and a power contact. All contact arrangements are provided at least in part with insulation-based slots, and each contact can alternately form an effective insulation.

  Each contact of the present invention is divided into a front end portion, an intermediate portion, and a rear end portion. The intermediate portion is connected between the front end portion and the rear end portion. The front end is connected to a corresponding electrical connector (eg, a socket). The rear end is connected to the substrate. The intermediate portion is connected to the front end portion from the bent portion and is connected to the rear end portion from the bent portion. The end of the rear end of various contacts is used to connect to the substrate. In the present embodiment, the end of the rear end is a surface mount leg. The end of the front end of the various contacts is used to connect to a corresponding electrical connector. In order to meet the requirements of the electrical connector and the contact arrangement described above, the front end portion is provided with respective bent portions.

  The rear end of the present invention is a surface mounting leg and a through hole mounting leg. In other embodiments, adjacent through-hole mounting legs are alternately spaced. When the through-hole mounting leg and the substrate are soldered, the adjacent through-hole mounting leg and the soldering point may be increased to avoid radio interference.

  In the present invention, the signal differential pair and the signal differential pair are arranged on both sides of the signal differential pair. A power contact is spaced between the signal differential pair and the signal differential pair. The contact of the electrical connector has an effect of reducing cross talk by transmission at high speed and high frequency.

The perspective view which shows the electrical connector of this invention. The front view which shows the electrical connector of this invention. The perspective view which shows the electrical connector of this invention. The top view which shows the electrical connector of this invention. The top view which shows the electrical connector of this invention. The perspective view which shows the electrical connector of this invention. The perspective view which shows the electrical connector of this invention. The side view which shows the electrical connector of this invention. The side view which shows the electrical connector of this invention. The perspective view which shows the electrical connector of this invention. The side view which shows the electrical connector of this invention. The perspective view which shows the electrical connector of this invention. The side view which shows the electrical connector of this invention. The perspective view which shows the electrical connector of this invention. The top view which shows the electrical connector of this invention. The rear view which shows the electrical connector of this invention. The side view which shows the electrical connector of this invention.

(One embodiment)
As shown in FIGS. 1 and 2, the electrical connector, that is, the plug 100 of this embodiment includes a metal case 104, an insulating base 102, and a contact arrangement. The metal case 104 is coated on the outside of the insulating base 102 having a contact arrangement. The metal case 104 can avoid radio interference when grounding the outside. The plug 100 is divided into two types of contact arrangements, and other species are elongated from the seed contact arrangement. In addition, the end 104b of the plug 100 is connected to the signal cable and covered.

As shown in FIGS. 3, 4 and 5, the first terminal array 106 includes two pairs of differential pair contacts and a ground contact 106c. The signal contacts 106a and 106b are a pair of signal differential pairs, and the signal contacts 106d and 106e are another pair of signal differential pairs. The second terminal array 108 includes a pair of second signal differential pairs 108b and 108c, a ground contact 108d, and a power contact 108a. All of the contact arrangements are provided with at least a part of the slot 102a of the insulating base 102, and each contact can alternately form effective insulation. As shown in the drawing, the signal differential pair is indicated by S , the signal differential pair is indicated by S , the power contact is indicated by V , and the ground contact is indicated by G.

As shown in FIG. 5, the contact array 200 is connected to a soldering point of the substrate 130. The first signal differential pairs 106a and 106b and the third signal differential pairs 106d and 106e are disposed on both sides of the second signal differential pairs 108b and 108c. The first signal differential pair 106a, 106b and the second signal differential pair 108b, 108c are separated by a power contact 108a. The third signal differential pair 106d, 106e and the second signal differential pair 108b, 108c are separated by a ground contact 108d. In addition, the two signal contacts of the second signal differential pair 108b and 108c are separated by a ground contact 106c. Looking at the entire electrical connector, each contact of the contact array 200 is provided in a single row in the order of S 1 , S 2 , V 2 , S 1 , G 3 , S 1 , G 2 , S 3 , S 3 from top to bottom.

  By the contact arrangement 200 described above, the two signal contacts of the first signal differential pairs 106a and 106b of the first terminal arrangement 106 are closely adjacent to each other, and the power contact and the ground contact are not separated from each other. The two signal contacts of the third signal differential pair 106d, 106e of the first terminal array 106 are closely adjacent to each other, and the power contact and the ground contact are not separated from each other. The purpose of providing the contact arrangement 200 is that the signal differential pair is not separated by the power contact and the ground contact. First, the effect of signal differential pairs and other contacts transmitting signals is minimized. That is, it is very important to reduce crosstalk in the high-speed and high-frequency transmission of the first terminal array 106.

  As shown in FIGS. 6 and 7, each contact is divided into a front end portion 120a, an intermediate portion 120b, and a rear end portion 120c. The intermediate part 120b is connected between the front end part 120a and the rear end part 120c. The front end 120a is connected to a corresponding electrical connector (for example, a socket). The rear end 120 c is connected to the substrate 130. The intermediate part 120b connects the front end part 120a from the first bent part 122b and connects the rear end part 120c from the second bent part 122a. The end of the rear end portion 120 c of various contacts is used to connect to the substrate 130. In this embodiment, the end of the rear end 120c is a surface-mounted leg. The end of the front end 120a of various contacts is used to connect to the corresponding electrical connector. In order to meet the requirements of the electrical connector and the above-described contact arrangement, the front end portion 120a includes respective bent portions.

  In the front end portion 120a of the signal contact 106b, the terminal that bends twice approaches the second signal differential pair 108b, 108c from the intermediate portion 120b. In the front end portion 120a of the signal contact 106d, the end that is bent twice approaches the second signal differential pair 108b and 108c from the intermediate portion 120b. At the front end portion 120a of the power contact 108a, the end that bends twice (turns at a right angle) approaches the second signal differential pair 108b, 108c from the intermediate portion 120b. At the front end portion 120a of the ground contact 108d, the end that bends twice (turns at a right angle) approaches the second signal differential pair 108b, 108c from the intermediate portion 120b. When the contact arrangement is viewed from the front end 120a to the rear end 120c of the contact arrangement, the front ends 120a of the signal contacts 106a and 106b are provided on both sides of the power contact 108a, and the front ends of the signal contacts 106d and 106e. The ends of the portion 120a are provided on both sides of the ground contact 108d.

The second bent portion 122a and the first bent portion 122b are formed with a right angle (90 ° angle or the like is good). According to other embodiments, the second bent portion 122a and the first bent portion 122b may form non-right angles depending on the shape of the insulating base 102. And the ends of the front end portion 120a of the contact array 106 are all upwardly curved, become the largest distance D _1, the ends of the front end portion 120a of the contact array 108, up and then down curved, the largest distance D ₂ It has become. In the contact array 108, the contacts 108a and 108d are formed longer than the contacts 108b and 108c.

  As shown in FIGS. 8 and 9, the present embodiment is different from FIGS. 6 and 7 and the leg portion at the end of the rear end portion 120 c. The end of the rear end portion 120c is a leg portion for through-hole mounting.

  As shown in FIGS. 10 and 11, the present embodiment differs from FIGS. 8 and 9 and the arrangement of the leg positions at the end of the rear end portion 120c. Adjacent through-hole mounting legs 124b are alternately spaced. When the through-hole mounting leg 124b and the substrate 230 are soldered, if the soldering point between the adjacent through-hole mounting leg 124b is increased, radio interference is avoided. In the present embodiment, the surface-mounted leg portion 124a of FIGS. 6 and 7 can be applied.

  As shown in FIGS. 12 and 13, in the present embodiment, the arrangement of the above-described example and the type of leg portion at the end of the rear end portion 120c are different. The present embodiment includes surface-mounted leg portions 124a and through-hole mounted leg portions 124b, which are alternately inserted and inserted. The surface mounting leg 124 a is soldered to the surface of the substrate 130, and the through hole mounting leg 124 b is formed by inserting a hole in the substrate 130.

  As shown in FIGS. 14 and 15, the electrical connector, that is, the socket of the present embodiment is divided into two types of contact arrangements, and the other types are made longer than the seed contact arrangements.

  The first terminal array 206 includes two pairs of differential pair contacts and a ground contact 206c. The signal contacts 206a and 206b are a pair of signal differential pairs, and the signal contacts 206d and 206e are another pair of signal differential pairs. The second terminal array 208 includes a pair of signal differential pairs 208b, 208c, a ground contact 208d, and a power contact 208a.

Hereinafter, the procedure of the contact arrangement 200 will be described in which the contact arrangement 200 connects the soldering points of the substrate 230. The signal differential pairs 206a and 206b and the signal differential pairs 206d and 206e are arranged on both sides of the signal differential pairs 208b and 208c. The signal differential pair 206a, 206b and the signal differential pair 208b, 208c are separated by a power contact 208a. The signal differential pairs 206d and 206e and the signal differential pairs 208b and 208c are separated by a ground contact 208d. In addition, the two signal contacts of the signal differential pairs 208b and 208c are separated by a ground contact 206c. Looking at the entire electrical connector, each contact of the contact arrangement 200 is provided in a single row in the order of S 1 , S 2 , V 2 , S 1 , G 3 , S 1 , G 2 , S 3 , S 3 from top to bottom.

  With the contact arrangement 200 described above, the two signal contacts of the signal differential pairs 206a and 206b of the first terminal arrangement 206 are closely adjacent to each other, and the power contact and the ground contact are not separated from each other. The two signal contacts of the signal differential pairs 206d and 206e of the first terminal array 206 are closely adjacent to each other, and the power contact and the ground contact are not separated from each other. The purpose of providing the contact arrangement 200 is that the signal differential pair is not separated by the power contact and the ground contact. First, the effect of signal differential pairs and other contacts transmitting signals is minimized. That is, it is very important to reduce crosstalk in the high-speed and high-frequency transmission of the first terminal array 206.

  As shown in FIGS. 16 and 17, each contact is divided into three parts: a front end part 220a, an intermediate part 220b, and a rear end part 220c. The intermediate part 220b is connected between the front end part 220a and the rear end part 220c. The front end 220a is connected to a corresponding electrical connector (for example, a plug). The rear end portion 220 c is connected to the substrate 230. The intermediate part 220b connects the front end part 220a from the second bent part 222b (90 degree angle or the like is good) and connects the rear end part 220c from the first bent part 222a (90 degree angle or the like is good). In the present embodiment, the end of the rear end 220c is a surface-mounted leg. The end of the front end 220a of various contacts is used to connect to the corresponding electrical connector. In order to meet the requirements of the electrical connector and the above-described contact arrangement, the front end portion 220a includes respective bent portions.

  At the front end portion 220a of the signal contact 206b, the end that is bent twice approaches the signal differential pairs 208b and 208c from the intermediate portion 220b. In the front end portion 220a of the signal contact 206d, the end that is bent twice approaches the signal differential pairs 208b and 208c from the intermediate portion 220b. At the front end portion 220a of the power contact 208a, the end that bends twice (turns at a right angle) approaches the signal differential pair 208b, 208c from the intermediate portion 220b. At the front end portion 220a of the ground contact 208d, the end that is bent twice (turned at a right angle) approaches the signal differential pair 208b, 208c from the intermediate portion 220b. By bending as described above, the position of the contact matches the standard of the electrical connector. Alternatively, any modification or change having an effect equivalent to that of the present invention made without departing from the spirit of the present invention belongs to the claims of the present invention.

  As described above, the electrical connector of the present embodiment has the following advantages when used.

  With the above-described contact arrangement 200 of the present invention, the two signal contacts of the first signal differential pairs 106a and 106b of the first terminal arrangement 106 are closely adjacent to each other, and the power contact and the ground contact are separated from each other. Absent. The two signal contacts of the third signal differential pair 106d, 106e of the first terminal array 106 are closely adjacent to each other, and the power contact and the ground contact are not separated from each other. The purpose of providing the contact arrangement 200 is that the signal differential pair is not separated by the power contact and the ground contact. First, the effect of signal differential pairs and other contacts transmitting signals is minimized. That is, it is very important to reduce crosstalk in the high-speed and high-frequency transmission of the first terminal array 106.

  The adjacent through-hole mounting legs 124b of the present invention are alternately spaced. When the through-hole mounting leg portion 124b and the board 230 are soldered, the adjacent through-hole mounting leg portion 124b and the soldering point may be increased, thereby avoiding radio wave interference. The present embodiment can be applied to the surface-mounted leg portion 124a of the other examples.

  The above description is merely an embodiment of the present invention, and does not limit the scope of the present invention, and can achieve simple modifications and the same effects that can be made based on the contents of the specification and drawings of the present invention. Any structural changes are within the scope of the claimed invention.

  100: plug, 102: insulation base, 102a: slot, 104: metal case, 106: first terminal arrangement, 106a to 106e: contact, 108: second terminal arrangement, 108a to 108d: contact, 120a: Front end portion, 120b: intermediate portion, 120c: rear end portion, 122a: second bent portion, 122b: first bent portion, 124a: leg portion for surface mounting, 124b: leg portion for mounting through hole, 130: substrate, 200 : Contact arrangement, 206: first terminal arrangement, 206a to 206e: contact, 208: second terminal arrangement, 208a to 208d: contact, 220a: front end portion, 220b: intermediate portion, 220c: rear end portion, 222a: first bent portion, 222b: second bent portion, 230: substrate.

Claims (5)

An insulating base having a slot;
A first signal differential pair, a second signal differential pair, and a third signal differential pair are provided fixed to the slot of the insulating base, and the first signal differential pair is provided. A contact arrangement having a power contact and a ground contact spaced apart from each other, wherein the first signal differential pair and the third signal differential pair are provided on both sides of the second signal differential pair;
A metal case coated on the exterior of the insulating base having the contact arrangement;
An electrical connector comprising:   Each contact of the contact arrangement is provided with an intermediate portion, a front end portion, a rear end portion, a first bent portion, and a second bent portion, and the intermediate portion is between the front end portion and the rear end portion. The terminal structure of the electrical connector according to claim 1, wherein the intermediate portion connects the front end portion from the first bent portion and connects the rear end portion from the second bent portion.   The terminal structure of the electrical connector according to claim 2, wherein a terminal portion of the rear end portion of the contact arrangement is provided with a surface mounting leg portion.   The electrical connector according to claim 3, wherein the rear end of the contact arrangement is provided with a through-hole mounting leg.   5. The electrical connector according to claim 4, wherein the end of the rear end portion of the contact arrangement is provided with the surface-mounting leg portion and the through-hole-mounting leg portion being alternately spaced from each other.

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