JPH05135826A - Impedance matching type electric connector - Google Patents

Abstract

PURPOSE:To obtain an electric connector which has a relatively stable impedance and a low crosstalk by forming a wide male conductor and a gland shell in a strip line structure for male signal terminals. CONSTITUTION:In an impedance conforming type electric connector which consists of a plug connector member 30 and a jack connector member 35, a plain and wide male connector 32 and a gland shell 34 form a strip line structure for a first and a second male signal conductor 33. And the member 35 is composed of a jack housing 36 which consists of an insulator material, a wide female conductor 37, and female signal conductors 38 at the first and second lines. By such a constitution, the desired specific impedance can be obtained by the strip line structure, it can be conformed with the specific impedance of a mounted printed wiring plate, and an influence of noise is small, and an impedance matching type electric connector which can obtain a stable impedance and a small crosstalk can be obtained.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an impedance-matching type electrical connector for electrical connection between a printed wiring board comprising a plug connector member and a jack connector member engaging with the plug connector member.

[0002]

2. Description of the Related Art With recent advances in high-speed signal processing in computers, multi-pole connectors for computers have become
In order to prevent signal reflection at the connector, it is required to realize impedance characteristics matching the impedance characteristics of the printed wiring board or cable and low crosstalk between signals. In order to meet such demands for high-speed signal processing, it is necessary to consider printed wiring boards, cable wiring, and connector wiring as transmission lines rather than simply connecting lines. That is, it is desirable to keep the positional relationship (cross-sectional shape) between the signal and the ground constant so that the electromagnetic waves around the signal line are not disturbed.

Types of transmission include (A) unbalanced transmission using a signal conductor and a ground conductor, and (B) balanced transmission using a plus signal conductor and a minus signal conductor. Unbalanced transmission is generally used for digital transmission in a printed wiring board or in a housing. The unbalanced transmission is further classified into the following three types according to the positional relationship between the signal conductor and the ground conductor. That is, a coaxial structure in which the signal conductor of the core is surrounded by a cylindrical ground conductor via a dielectric layer (insulating layer),
A stripline structure in which a signal conductor is sandwiched by a pair of parallel ground planes via a dielectric layer, and a microstripline structure in which a ground plane is arranged in parallel only on one side of the signal conductor via a dielectric layer. There is.

The transmission characteristics differ between the stripline structure and the microstripline structure. With the stripline structure, noise and crosstalk are relatively small, signals are less susceptible to external electromagnetic fields, and impedance characteristics are stable. In the microstrip line structure, the signal is relatively affected by the external electromagnetic field (small shield effect), and the impedance characteristic is unstable. Further, the signal is affected by the electromagnetic field from the signal conductor itself according to the arrangement of the dielectric material and the conductor, and the crosstalk increases.

When the corresponding members have the same dimensional relationship,
The impedance changes between the stripline structure and the microstripline structure. It is known that, where ε is the dielectric constant of the dielectric, d is the diameter when the signal conductor is round, and h is the distance between the center of the signal conductor and the ground plane, the impedance Z ₀ can be calculated, for example, by the following formula. ing.

In the case of the strip line structure,

[Equation 1] In case of microstrip line structure,

[Equation 2]

Conventionally, a printed wiring board is formed in a multi-layered structure, and generally, the innermost layer is assigned to a ground and a power source, so that it has a microstrip line structure in which a ground plane is located on one side of a signal conductor. .. An impedance matching type electrical connector having an impedance characteristic that matches the impedance characteristic of the printed wiring board has been proposed in order to be connected to such a printed wiring board. For example, Japanese Utility Model Publication No. 49-6543 discloses an electric connector connected to a printed wiring board having a microstrip line structure. As shown in FIGS. 8 to 10, the electric connector includes a plug connector member 50 and a jack connector member 52 that engages with the plug connector member 50. 9 is a sectional view of the jack connector member 52, and FIG. 10 is a sectional view of the plug connector member 50.

The plug connector member 50 comprises a plug housing 54 of insulating material having three parallel rows of holes, each of these three rows of holes having a first row of male signal terminals 5.
6, the male signal terminals 58 of the second row, and the flat and wide male conductor 60 are fitted together. The wide male conductor 60 is arranged between the male signal terminals 56 of the first row and the male signal terminals 58 of the second row to form a microstrip line structure. The jack connector member 52 has three rows of holes 64, 6
A jack housing 62 of insulating material having 6, 68 is provided. A flat, wide female conductor 70 is inserted into the central hole 68 to receive the wide male conductor 60. The upper and lower female signal terminals 72, 74 are respectively provided with the upper and lower holes 64,
66, and engages with the female signal terminals 56 and 58. The wide female conductor 70 also forms a microstrip line structure for the female signal terminals 72 and 74. Further, a shield case 76 is provided on the jack housing 62. The shield case 76 shields external electromagnetic waves and does not control the impedance as a stripline structure.

In this connector, the wide male conductor 60
Protrudes longer than the female signal terminals 56, 58, and the wider male conductor 60 first fits in the central hole 68 of the jack housing 62.
And acts as a guide when the plug connector member 50 is engaged with the jack connector member 52. Further, the wide male conductor 60 has a slit 78 in the central portion, which cooperates with a guide wall 80 forming a discontinuous portion of the central hole 68 of the jack housing 62 so that the plug connector member 50 can be connected to the jack connector member 52. It acts as a guide when engaged with.

US Pat. No. 4,762,500 also discloses an impedance matching type electrical connector having a microstrip line structure. This connector also includes a substantially flat and wide ground conductor and two rows of signal conductors on both sides thereof to form a microstrip line structure.

[0011]

In recent years, printed wiring boards have become multi-layered, and the innermost layer is not always assigned to the ground and the power source, and the ground conductor and the power source conductor are arranged in a plurality of layers. It has become to. Therefore, the signal conductor is arranged between the ground conductor and the power supply conductor or between the ground conductor and the ground conductor.
Since the constant-voltage power supply conductor can be regarded as equivalent to the ground in terms of high frequency, a stripline structure in which the ground planes are located on both sides of the signal conductor is formed.

In principle, even if the connector has a microstrip line structure, it is possible in principle to design a connector having desired impedance characteristics so as to match the impedance characteristics of the multilayer printed wiring board having the strip line structure. Is. To this end, it is necessary to properly select the distance h between the center of the signal conductor and the ground plane in relation to the diameter d of the signal conductor. But,
In practice, the greater the density of signal conductors, the smaller the diameter of the signal conductors and the smaller the pitch between adjacent signal conductors. The microstripline structure connector having the impedance characteristic selected under such conditions has a problem that the impedance becomes relatively unstable and the crosstalk becomes high. An object of the present invention is to provide an impedance matching type electrical connector having relatively stable impedance and low crosstalk.

[0013]

An impedance matching type electrical connector according to the present invention is an impedance for electrical connection between a printed wiring board comprising a plug connector member 30 and a jack connector member 35 engaging with the plug connector member. A matched type electrical connector, wherein the plug connector member 30 includes a plug housing 31 made of an insulating material, the plug housing having an outer peripheral surface 31a around an axis and a first plane parallel to the axis. At least one wide hole 31e provided, a first row of small holes 31f provided in a second plane parallel to the first plane, and at least one parallel to the first plane A second row of small holes 31g provided in a third plane opposite the first row of small holes with respect to one wide hole, the outer peripheral surface having The at parallel said at the first plane 1
First wide second hole and first and second opposite flat outer surface portions 31 in overlapping relationship with the first and second rows of small holes
c, 31d, the plug connector member 30 further fitting into at least one generally flat wide male conductor 32 fitted into the at least one wide hole, and the first row of small holes, respectively. First row male signal terminals 3 to be combined
3 and a second fitted in each of the smaller holes in the second row
Row of male signal terminals 33 and a conductor ground shell 34 attached to the outer peripheral surface of the plug housing, the ground shell 34 being a first flat shell that covers the first flat outer surface portion. A portion 34a and a second flat shell portion 34b overlying the second flat outer surface portion, the distance between the first flat shell portion and the male signal terminals of the first row. Is substantially equal to the distance between the male signal terminals of the first row and the at least one wide male conductor,
The distance between the second flat shell portion and the male signal terminals of the second row is at least 1 with the male signal terminals of the second row.
Substantially equal to the distance between the two wide male conductors, the impedance of the male signal terminals of the first and second rows being controlled by the at least one wide male conductor and the ground shell, and The jack connector member 35
A jack housing 36 of insulating material, at least one wide female conductor 37 that engages the at least one wide male conductor 32, and a first row that engages the male signal terminals 33 of the first row. Female signal terminal 38 and a female signal terminal 38 of the second row that engages with the male signal terminal 33 of the second row.

[0014]

In the above construction, the male signal terminals of the first and second rows are respectively arranged between the at least one wide male conductor and the ground shell via the insulating material forming the plug housing, and thus at least one. The one wide male conductor and the ground shell form a stripline structure for the male signal terminals of the first and second rows. Therefore,
According to the present invention, an electrical connector having relatively stable impedance and low crosstalk can be obtained.

[0015]

1 to 4 show an electrical connector 1 according to the present invention.
0, this connector 10 is a plug connector member 30
And a jack connector member 35 engageable with the plug connector member 30 and used for electrical connection between printed wiring boards (not shown). FIG. 2 is a partially enlarged cutaway perspective view of the plug connector member 30, and FIG. 3 is a partially enlarged cutaway perspective view of the jack connector member 35.

As shown in FIGS. 1, 2 and 4, the planer member 30 is a plug housing 3 made of an insulating material.
1, the plug housing 31 has an axis as indicated by an arrow in FIG. 1, along which the plug connector member 30 can be engaged with the jack connector member 35. The plug housing 31 has an outer peripheral surface 31a having a substantially rectangular cross section and an outer peripheral shoulder 31b adjacent to one end of the plug housing 31. The outer peripheral surface 31a includes first and second opposing flat outer surface portions 31c and 31d extending along the long sides of the rectangular cross-section.

The plug housing 31 is further provided with a plurality of wide holes 31e provided in a first plane parallel to the axis.
A first row of small holes 31f provided in a second plane parallel to the first plane and the first hole with respect to the at least one wide hole 31e parallel to the first plane. The second provided in the third plane opposite to the row of small holes 31f
Row of small holes 31g. The first and second outer surface portions 31c, 31d, the wide holes 31e, the first row of small holes 31f, and the second row of small holes 31g all extend perpendicular to the plane of the paper of FIG. 4 and thus all overlap. Parallel to each other.

A plurality of flat wide male conductors 32 are fitted in the wide holes 31e, respectively. The flat and wide male conductor 32 is composed of at least one ground conductor and at least one power conductor arranged in a line on the first plane. As shown in FIGS. 1 and 2, a wide male conductor 32
Each of which has a sharpened end (contact) 32a for coupling to a corresponding female conductor and a branched lead end (contact) 32b for coupling to a printed circuit board (not shown). Have. The lead end 32b projects outward from the outer peripheral shoulder 31b of the plug housing 31.

The male signal terminals 33 of the first row are respectively the first
, And the male signal terminals 33 in the second row are fitted in the small holes 31g in the second row, respectively. Each of the first and second rows of male signal terminals 33 has a sharpened end (contact) 33a for coupling to a corresponding female signal conductor and a coupling to a printed circuit board (not shown). Lead end (contact) 33b for
Have and. The lead end 33b is the plug housing 31.
The outer peripheral shoulder portion 31b is bent and protrudes outward in a zigzag arrangement. The wide male conductor 32 is made of a hard and flat plate of good electrical conductor, and the male signal terminal 33 is made of a thin rod of good electrical conductor.

A ground shell 34 of a good electrical conductor is attached to the outer peripheral surface 31a of the plug housing 31. The ground shell 34 is the outer peripheral surface 31a of the plug housing 31.
Is formed in a continuously closed cylindrical shape so as to surround the plug housing 31 and has a rectangular cross-sectional shape so as to be in close contact with the plug housing 31. Therefore, the ground shell 34 includes the first flat shell portion 34a that covers the first flat outer surface portion 31c of the outer peripheral surface 31a of the plug housing 31 and the second flat outer surface portion 31d that covers the second flat outer surface portion 31d. And a shell portion 34b.

As shown in FIG. 5, the ground shell 3
4 forms a stripline structure for the male signal terminal 33. Therefore, the first flat shell portion 34a has a distance between the first flat shell portion 34a and the male signal terminals 33 of the first row that is equal to the male signal terminals 3 of the first row.
3 and the at least one wide male conductor 32 are formed to be substantially equal to each other, and the second flat shell portion 34b includes a second flat shell portion 34b and a second row. Is formed to be substantially equal to the distance between the male signal terminals 33 of the second row and the at least one wide male conductor 32.

The ground shell 34 is the plug housing 3
1 is arranged on the outer peripheral surface 31a in abutting relation with the outer peripheral shoulder 31b, and the length thereof is such that one end of the ground shell 34 abuts on the outer peripheral shoulder 31b of the plug housing 31 and the other end of the plug housing 31 The jack connector member 35 is extended beyond the portion 31h.

The ground shell 34 has a tongue 3 on its short side.
4c, the tongue 34c is bent inward so as to be electrically connected to the wide male conductor 32 through the hole of the plug housing 31. The tongue 34c engages with the wall of the plug housing 31 and also has a function of mechanically coupling the ground shell 34 to the plug housing 31.

The ground shell 34 further has a pair of outwardly bulging arcuate guide walls 34d at opposite corners of the long side of the rectangular cross section, and the wide male conductor 32 is widened by the wide width of the jack connector member 35. Of the corresponding female conductor.

As shown in FIGS. 1, 3, and 4, the jack connector member 35 includes a jack housing 36 made of an insulating material and a wide female conductor 37 that engages with the wide male conductor 32 of the plug housing 31. A first row of female signal terminals 38 engaging with the first row of male signal terminals 33;
Row of male signal terminals 33 and second row of female signal terminals 38 that engage.

The jack housing 36 has an outer peripheral surface 36a having a substantially rectangular cross-section that matches the outer peripheral surface 31a of the plug housing 31. Therefore, as shown in FIG. 4, the plug housing 31 is integrated with the jack housing 36. When they do, both ends will come into contact with each other. The outer peripheral shoulder portion 36 b of the jack housing 36 is provided at the end opposite to the plug housing 31. An outer peripheral surface 36a of the jack housing 36 has first and second opposing flat outer surface portions 36 extending along long sides of the rectangular cross section.
c, 36d, and the jack housing 36,
A plurality of wide holes 36 for inserting the wide female conductor 37
e, and the first and second rows of small holes 36f, 36g for inserting the first and second rows of female signal terminals 38.

Each of the wide female conductors 37 is diverted to receive a sharpened end 32a of the male conductor 32 and a female end (contact) 37a and to another printed circuit board (not shown). And a branched lead end (contact) 37b for coupling. Each of the female signal terminals 38 has a female end (contact) 38a for receiving the sharpened end 33a of the male signal conductor 33 and a lead end for coupling to another printed circuit board (not shown). Part (contact) 38
b and. The lead ends 38b of the female signal terminals 38 are also bent so as to form a staggered arrangement. The wide female conductor 37 is made of a combination of elastic flat plates of good electric conductor, and the female signal terminal 38 is made of a thin rod of good electric conductor.

The jack housing 36 has a pair of protrusions 36c at opposite corners. This protrusion 36c engages with the guide wall 34d of the ground shell 34 to help the wide male conductor 32 engage with the corresponding wide female conductor 37 of the jack connector member 35 and prevent incorrect insertion. To do.

As shown in FIG. 4, with the end of the jack housing 36 in contact with the end of the plug housing 31, the ground shell 34 extends beyond the plug housing 31 and into the jack housing 36. There is. Preferably, the ground shell 34 at least partially covers the outer peripheral surface 36 a of the jack housing 36 so that a part of the ground shell 34 overlaps the wide female conductor 37. Preferably, the ground shell 34 extends between the outer peripheral shoulder 31b of the plug housing 31 and the outer peripheral shoulder 36b of the jack housing 36. In this way, the ground shell 34 cooperates with the wide female conductor 37 of the jack housing 36 to cooperate with the female signal terminal 3
Form a stripline structure for 8.

FIG. 6 is a view showing a jack connector member 35 according to the second embodiment. This jack connector member 3
5 has the same structure as the jack connector member 35 of FIG. However, the jack connector member 3 of FIG.
5 is taller than the jack connector member 35 of FIG. 3, and the ground shell 34 cannot completely cover the wide female conductor 37 of the jack housing 36. In this case, another ground shell 39 is attached to the jack housing 36. Preferably, the first ground shell 34 extends to the jack housing 36 and abuts the outer peripheral shoulder portion 36b of the jack housing 36, and the second ground shell 39 is attached to the outer peripheral shoulder portion 36b of the jack housing 36. The ground shell 34 and the second ground shell 39 are substantially continuous. The second ground shell 39 has a wide female conductor 37.
It has a tongue 39a on its short side for electrical connection to.

The following table shows the impedance and crosstalk test results for the three connectors A, B and C. The connector A is the connector 10 of the first embodiment, and the connector B has the same shape as the connector 10 and has the ground shell 34, but the ground shell 34 is not connected to the ground. The connector C has the same shape as the connector 10, but the plug housing 31
I did not attach the ground shell 34 to
It has a microstrip line structure.

[0032]

[Table 1]

The near end of the crosstalk is a value measured on the pulse applying side (jack side), and the far end is a value measured on the plug side. From this result, it can be seen that the connector A can achieve a smaller crosstalk as compared to the other connections. Moreover, the connector B showed the impedance close to the connector A. Although the reason is not clear, since the number of signal terminals that sent signals in the test is small and the ground shell 34 is large, the ground shell 34 was not connected to the ground in the test but was connected to the ground. It seems that the potential was also stable. In actual use, ground shell 34 should be connected to ground. Furthermore, the signal terminal 3 of each column
It is preferable that 3, 38 are arranged in the center between the wide male (female) conductor 32 (37) and the flat shell portions 34a, 34b of the ground shell 34 in order to reduce crosstalk.

The electrical connector 10 has, for example, 100 male signal terminals 33 arranged in a plug housing 31 having a length of 64 mm along the long side portion and a length of 4 mm along the short side portion. The height of the electrical connector 10 was about 20 mm. The electrical connector 10 is suitable for high-speed signal processing at a level of about 1 GHz, for example. Therefore, in order to effectively reduce crosstalk at such high frequency levels, it is preferable to select the insulating material of the plug housing 31 and jack housing 36 from those having a low dielectric constant. It has been found that it is preferable to use liquid crystal polymer as an insulating material for the plug housing 31 and the jack housing 36. Further, it has been found that the liquid crystal polymer has sufficient strength to obtain the plug housing 31 and the jack housing 36 having the fine wall structure having the above-described dimensions and has heat resistance in the later soldering step. .. Further, it has been found that the liquid crystal polymer has excellent fluidity in the mold in the molding process.

FIG. 7 is a diagram showing a plug connector member 30 according to the third embodiment. The planner member 30 includes a plug housing 31, a wide male conductor 32, a ground shell 34, and other members. Other members are the male signal terminals 33 and the like in the first and second rows, as in the plug connector member 30 of FIG. The tongue 34c of the ground shell 34 in FIG. 2 is the tongue 41 in FIG. The tongue 41 extends from one end of the ground shell 34, and is bent along the end surface of the plug housing 31 on which the branched lead end 32b of the wide male conductor 32 projects. The tongue 41 has the hole 40, and the wide male conductor 3
One of the two branched lead ends 32b passes through this hole 40, thus achieving an electrical connection between the ground shell 34 and the wide male conductor 32 and a mechanical connection between the ground shell 34 and the plug housing 31. It is supposed to do.
When the outer peripheral shoulder 31b is provided adjacent to the end of the plug housing 31, a slit is provided in the outer peripheral shoulder 31b, and the tongue 41 can be guided to the end surface of the plug housing 31 through the slit. .. Further, the tongue 41 of FIG. 7 can be used instead of the tongue 39a of FIG.

[0036]

As described above, according to the present invention,
A desired characteristic impedance can be obtained by the strip line structure, and matching with the characteristic impedance of the mounted wiring board can be achieved. Further, since it has a stripline structure, an impedance matching type electrical connector that is less affected by noise, can obtain stable impedance, and has less crosstalk can be obtained.

[Brief description of drawings]

FIG. 1 is a perspective view showing a first embodiment of the present invention.

FIG. 2 is a partially cutaway perspective view showing the plug connector member of FIG.

3 is a partially cutaway perspective view showing the jack connector member of FIG. 1. FIG.

4 is an assembled cross-sectional view of the connector of FIG.

5 is a cross-sectional view taken along line bb of FIG.

FIG. 6 is a perspective view showing a jack connector member of a second embodiment.

FIG. 7 is a perspective view showing a plug connector member of a third embodiment.

FIG. 8 is a diagram showing a conventional technique.

9 is a perspective view showing the jack connector member of FIG. 8. FIG.

FIG. 10 is a perspective view showing the plug connector member of FIG.

[Explanation of symbols]

 30 ... Plug connector member 31 ... Plug housing 32 ... Wide male conductor 33 ... Male signal conductor 34 ... Ground shell 35 ... Jack connector member 36 ... Jack housing 37 ... Wide female conductor 38 ... Female signal conductor

Claims (6)

[Claims] 1. A plug connector member (30) and a jack connector member (35) engaging the plug connector member.
An impedance-matching type electrical connector for electrical connection between printed wiring boards comprising: a plug connector member (30) provided with a plug housing (31) made of an insulating material; A peripheral surface (31a), at least one wide hole (31e) provided in a first plane parallel to the axis, and a second plane parallel to the first plane. A first row of small holes (31f) and the first with respect to the at least one wide hole parallel to the first plane.
A second row of small holes (31g) provided in a third plane opposite the row of small holes, the outer peripheral surface being parallel to the first plane and the at least one The plug connector member (30) further comprising wide holes and first and second opposing flat outer surface portions (31c, 31d) in overlapping relationship with the first and second rows of small holes. At least one generally flat wide male conductor (32) fitted in the at least one wide hole and a first row male signal terminal (32) respectively fitted in the small holes in the first row. 33), a second row of male signal terminals (33) which are respectively fitted in the small holes of the second row, and a conductor ground shell (34) mounted on the outer peripheral surface of the plug housing. The gland shell (34) has a first cover over the first flat outer surface portion. A flat shell part (34a), a second planar shell portion covering the flat outer surface portion of said 2 (34b)
And the distance between the first flat shell portion and the male signal terminals of the first row is between the male signal terminals of the first row and the at least one wide male conductor. Is substantially equal to the distance between the second flat shell portion and the male signal terminals of the second row and the male signal terminals of the second row and the at least one wide male conductor. And the impedance of the male signal terminals of the first and second rows is controlled by the at least one wide male conductor and the ground shell, and the jack connector member (35). ) Is a jack housing (36) made of an insulating material, at least one wide female conductor (37) engaging the at least one wide male conductor (32), and the first row of male signal terminals. A first row of female signal terminals (38) engaging with (33);
An impedance matching type electrical connector comprising: a second row of male signal terminals (33) and a second row of female signal terminals (38). 2. The ground shell is coupled to the flat wide male conductor for electrical connection to the wide male conductor and mechanical coupling to the plug housing. Item 1. The impedance matching type electrical connector according to Item 1. 3. The impedance matching type electrical connector according to claim 1, wherein the ground shell is formed in a continuously closed shape so as to surround the outer peripheral surface of the plug housing. 4. The plug housing has a first end portion on the printed wiring board side, a second end portion on the jack connector member side, and an outer peripheral shoulder portion adjacent to the first end portion. The impedance matching type electrical connector according to claim 1, wherein the ground shell is attached to the outer peripheral surface of the plug housing in a state of abutting on the outer peripheral shoulder portion. 5. The length of the ground shell is such that one end of the ground shell abuts the outer peripheral shoulder and the other end extends beyond the second other end of the plug housing to the jack connector member. The impedance matching type electrical connector according to claim 4, wherein the electrical connector is an impedance matching type electrical connector. 6. The gland shell has guide means and the jack housing has cooperating guide means to assist in engagement of the wide male conductor with the wide female conductor. The impedance matching type electrical connector according to claim 1.