瑞士专利CH714342A2 RJ-45 connector for high frequency applications.

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专利摘要:
An RJ-45 connector (10) for high frequency applications includes a housing (12, 16), a plurality of contact leads (50), and insulation displacement contacts. A printed circuit board (40) has a plurality of transmission paths connecting corresponding tongues and insulation displacement contacts. The plug (10) has a main coupling which contains a coupling between the tongues. The PCB also includes a compensation coupling arrangement that provides a smaller coupling compared to the main coupling. The compensation coupling is at most one half of the main coupling and has a different polarity from the main coupling. The compensation coupling is connected to a set of transmission paths at a position between the main coupling and the insulation displacement contacts.
公开号:CH714342A2
申请号:CH01390/18
申请日:2018-11-12
公开日:2019-05-15
发明作者:
申请人:Surtec Ind Inc；
IPC主号:

专利说明:

description
FIELD OF THE INVENTION The present invention relates to electrical connectors and more particularly relates to an RJ-45 connector for high frequency applications.
BACKGROUND OF THE INVENTION Electrical connectors such as RJ-45 connectors have been used for network applications. These connectors contain conductors, with pairs of conductors being provided for each transmission path. Plugs such as RJ-45 plugs have eight conductors or four pairs for four different transmission lines. These can include an inner pair and the shared pair. With standard RJ-45 plugs there is an enormous capacitive coupling between the tongues of the inner pair and the tongues of the split pair as well as the corresponding twisted cable wires.
In high speed or high frequency applications, capacitive coupling can degrade the performance of the male-female pair. A capacitive coupling or a capacitive reactance is a component of the impedance (Z) of the connector, where Z (impedance) = R (resistance) + jX (capacitive reactance + inductive reactance). One reason for the power-reducing capacitive coupling is in particular the arrangement of transmission paths with an inner pair of conductors, which is surrounded by a so-called split pair of conductors, namely a conductor on one side of the inner pair and another conductor on another side of the inner pair, the part of a single transmission path. Coupling (a capacitive reactance) is particularly problematic in the area of the inner pair and the divided pair at the plug contacts.
Because of the substantial capacitive variation caused by the arrangement of normal twisted pairs of wires and adjacent tongues, it is difficult to achieve high performance with an arrangement of normal twisted pairs and tongues. More and more high-performance connectors are using a printed circuit board (PCB) to replace twisted pairs when connecting to the tabs. Such tongues have assembly and electrical connection pins that connect each tongue with pin holders on the PCB which are then connected to individual wires of a cable. In this way, the uncertainty of tongues and twisted veins is eliminated. The circuit boards can use an additional coupling to increase coupling that occurs on the connector conductors. In high frequency applications, namely at frequencies raised to 2 GHz, for example in a Category 8 application, the coupling between tongues can no longer be treated as a combined capacitor; rather, they behave like coupled transmission lines. This means that the couplings are no longer linear in terms of frequency. However, the standard (TIA-568-C.2-1) requires a linear behavior of the connector couplings. The problem is compounded if there are couplings in the PCB circuits that add to the tongue couplings.
SUMMARY OF THE INVENTION It is an object of the invention to provide an RJ-45 connector for high frequency applications with better control of the linearity of the connector coupling (capacitive reactance) with respect to the frequencies. It is an object of the invention to provide an RJ-45 connector for high frequency applications that eliminates problems associated with compensating for phase changes due to the transmission line effect of the tabs. Especially for applications at higher frequencies, such as frequencies up to the 2 GHz range.
It is an object of the invention to provide an RJ-45 connector for high frequency applications that has better performance features compared to prior art connectors, especially better performance at higher frequencies.
According to the invention, a communication plug for high-frequency applications comprises a housing, a plurality of contact conductor tongues and insulation displacement contacts. A printed circuit board (PCB) has a multiplicity of transmission paths that connect corresponding tongues and insulation displacement contacts. The plug contains a main coupling, which comprises at least the coupling between immediately adjacent contact conductor tongues and corresponding connected circuit parts of the PCB. The PCB also includes a compensation coupling arrangement that offers a smaller coupling compared to the main coupling. The compensation coupling is at most half of the main coupling and has a different polarity from the main coupling. The compensation coupling is connected to a set of transmission paths at a position between the main coupling and the insulation displacement contacts.
An amount of the compensation coupling arrangement is advantageously less than 1/1 of an amount of the main coupling. The compensation coupling arrangement can advantageously be electrically connected to the contact conductor tongue at a path distance from the contact conductor tongues that is greater than 5 mm.
The corresponding connected circuit parts of the PCB advantageously further comprise a coupling arrangement in addition to the plurality of contact conductor tabs. The coupling arrangement forms a section of the main coupling.
CH 714 342 A2
The Télécommunications Industry Association (TIA) standard requires a certain coupling amount. The coupling arrangement is used to meet this requirement given the coupling to the tabs. Alternatively, however, the main coupling may be provided wholly or substantially by the lead tabs, such as by providing large tabs that meet the TIA requirement for a specific amount of coupling. [0010] The PCB may have a plurality of tongue conductor contact areas, which connect respective contact conductor tongues to the respective transmission paths associated therewith. The contact lead tabs may include an inner pair of lead tabs arranged side by side and in electrical contact with an inner pair of tongue lead contact areas of the plurality of tongue lead contact areas. The contact tabs may further include a split pair of tabs, each pair of split tabs being adjacent to a respective one of the inner pair of tabs and in electrical contact with a split pair of tab contact areas of the plurality of tab contact areas. The coupling arrangement may comprise a first coupling portion from a split pair to an inner pair, which is provided on the PCB and is electrically connected to one of the inner tongue contact area pair and is electrically connected to the adjacent split tongue contact area pair, providing capacitive coupling therebetween. The coupling arrangement may further comprise a second coupling portion from a split pair to an inner pair which is provided on the PCB and is electrically connected to another one of the inner tongue contact area pair and is electrically connected to the adjacent split tongue contact area pair, and has a capacitive coupling therebetween provides. The first coupling section from a split pair to an inner pair is connected to one of the inner tongue conductor contact area pair and the adjacent split tongue conductor contact area pair is spaced D apart therefrom. The second coupling portion from a split pair to an inner pair is connected to the other of the inner tongue contact pair and the adjacent split tongue contact pair is spaced D apart. The compensation coupling assembly includes a split-pair to inner-pair compensation coupling portion that is electrically connected to one of the traces connected to an area of the inner tongue contact area pair and electrically connected to one of the tracks connected to an area of the adjacent divided tongue contact area pair that is adjacent to the one of the traces connected to a region of the inner tongue conductor contact region pair, thereby providing capacitive coupling between them. The compensation coupling arrangement is spaced a distance d along the associated track from the compensation coupling arrangement to the conductor contact areas, where d »D.
The tongue conductor contact areas connect respective contact conductor tongues with the respective transmission paths associated with the PCB. Each tongue can have an advantageous shape, which contains a plug contact longitudinal section with a tongue contact length for contact with contact conductors of a receptacle and an elongated section which runs at an angle relative to the plug contact longitudinal section. The elongated section ends at a conductor contact section which has a contact area which makes electrical and physical contact with the respective tongue conductor contact region.
The housing may include one or more housing parts that support the plurality of conductor tabs and support the PCB and clamp the contact tabs and the PCB to press each of the plurality of contact tabs into contact with the associated one of the conductor contact areas of the PCB with a compressive force to provide a solderless electrical and physical connection between each of the contact tabs and a corresponding one of the transmission path tab contact areas.
Alternatively, the housing comprises one or more housing parts which carry the plurality of contact conductor tongues and carry the PCB, each of the contact conductor tongues comprising a plug contact section and a conductor pin integral with the plug contact section. In this case, the conductor contact areas comprise metallized through openings of the PCB, which receive one of the conductor pins, in order to provide electrical contact between each plug contact area and the associated contact conductor tongue. The conductor pins received in the metallized through openings insert the respective contact conductor tongue into the PCB.
The housing may include one or more housing parts that support the plurality of contact tabs and support the PCB.
By adding a small compensation coupling that is far enough from the main coupling, for example d »D, the small compensation reduces the coupling at low frequency, but has little additional impact on it at high frequency. This improves the linearity of the coupling. In particular, the tongues of a conventional connector can be treated like folded capacitors at lower frequencies (for example below 250 MHz). As such, their effect (impedance effect Zc) in the circuit is proportional to the frequency Zc = 1 / jœc if ω = 2πΡ In a high-frequency application, the treatment as merged capacitors (this assumption) is no longer valid. The contact tongues must be treated like transmission lines, i.e. as small capacitors that are connected in series at small intervals. Each small capacitor has one phase. This requires phase pointer analysis. If one considers only two small capacitors to explain the situation of the tongues at high frequency, at 100 MHz, the small distance between two capacitors causes a small phase difference, for example 0.5 °; therefore vector summing is very close to simply summing the amount of these two vectors. At much higher frequencies, for example 2 GHz, the increases
CH 714 342 A2
However, the phase difference is 20 times, for example 10 °. As such, vector summation must use vector summation and not simply the sum of these two vectors.
The invention solves this problem by adding a small compensating capacitor (in opposite polarity) with less than 1/10 of the amount of the main coupling. The main coupling is also controlled based on the fact that it is the coupling of the coupling arrangement and the coupling between the contact conductor tongues. The compensation coupling is provided by the small compensating capacitor, which is provided at a distance of more than 5 mm from the tongues. The small compensating capacitor can compensate for the combination effect of the main coupling at low frequencies (in parallel), but has a smaller effect at high frequencies. Therefore, the difference in the combination of capacitor couplings between low frequencies and high frequencies can be reduced and is more linearly proportional to the frequency.
The various features of novelty that characterize the invention are set forth with particularity in the claims attached to and forming a part of this disclosure. For a better understanding of the invention, its operational advantages and specific objects which are achieved by its uses, reference is made to the accompanying drawings and the description, in which preferred embodiments of the invention are shown.
BRIEF DESCRIPTION OF THE DRAWINGS
In the drawings:
[0018]
Fig. 1 is a perspective view of an RJ-45 connector according to the invention;
Fig. 2 is an exploded view of the connector of Fig. 1;
Fig. 3 is a cross-sectional view along a longitudinal direction of the connector of Fig. 1;
Figure 4 is a detailed view of Detail A of Figure 3;
Fig. 5 is a bottom view showing an underside lying on level 1 with a conductive layer surface of the printed circuit board of the connector of Fig. 1;
FIG. 6 is a cross-sectional view through the PCB between the top and bottom of the PCB showing a level 2 with a conductive layer surface located between the top and bottom of the PCB of the connector of FIG. 1;
7 is another cross-sectional view through the PCB between the top and bottom of the PCB, showing a level 3 with a conductive layer surface located between the top and bottom of the PCB of the connector of FIG. 1:
Fig. 8 is another cross-sectional view through the PCB between the top and bottom of the PCB showing a level 4 with a conductive layer surface located between the top and bottom of the PCB of the connector of Fig. 1;
Fig. 9 is another cross-sectional view through the PCB between the top and bottom of the PCB showing a level 5 with a conductive layer surface located between the top and bottom of the PCB of the connector of Fig. 1;
Fig. 10 is another cross-sectional view through the PCB between the top and bottom of the PCB showing a plane 6 with a conductive layer surface located between the top and bottom of the PCB of the connector of Fig. 1;
FIG. 11 is another cross-sectional view through the PCB between the top and bottom of the PCB showing a plane 7 with a conductive layer surface located between the top and bottom of the PCB of the connector of FIG. 1;
Fig. 12 is a plan view showing the upper underside lying on plane 8 with a conductive layer surface of the printed circuit board of the connector of Fig. 1;
Fig. 13 is a cross sectional view taken along a section line Xlll-Xl 11 of Fig. 3;
14 is a cross-sectional view in a plane passing through and along a conductive metal member
Longitudinal direction of the plug of Fig. 1 leads;
15 is a perspective view of another RJ-45 connector according to the invention;
CH 714 342 A2
Fig. 16 15 is an exploded view of the connector of FIG. 15; Fig. 17 Fig. 15 is a cross-sectional view along a longitudinal direction of the connector of Fig. 15; Fig. 18 Figure 17 is a detail view of Detail B of Figure 17; Fig. 19 Fig. 15 is a bottom view showing an underside lying on level 1 with a conductive layer surface of the printed circuit board of the connector of Fig. 15; Fig. 20 Fig. 15 is a cross-sectional view through the PCB between the top and bottom of the PCB showing a level 2 with a conductive layer surface located between the top and bottom of the PCB of the connector of Fig. 15; Fig. 21 Figure 15 is another cross-sectional view through the PCB between the top and bottom of the PCB showing a level 3 with a conductive layer surface located between the top and bottom of the PCB of the connector of Figure 15; Fig. 22 Figure 15 is another cross-sectional view through the PCB between the top and bottom of the PCB showing a level 4 with a conductive layer surface located between the top and bottom of the PCB of the connector of Figure 15; Fig. 23 Figure 15 is another cross-sectional view through the PCB between the top and bottom of the PCB showing a level 5 with a conductive layer surface located between the top and bottom of the PCB of the connector of Figure 15; Fig. 24 Figure 15 is another cross-sectional view through the PCB between the top and bottom of the PCB, showing a level 6 with a conductive layer surface located between the top and bottom of the PCB of the connector of Figure 15; Fig. 25 Figure 15 is another cross-sectional view through the PCB between the top and bottom of the PCB, showing a plane 7 with a conductive layer surface located between the top and bottom of the PCB of the connector of Figure 15; Fig. 26 Figure 15 is a top plan view showing the top underside lying on level 8 with a conductive layer surface of the printed circuit board of the connector of Figure 15; Fig. 27 Fig. 17 is a cross sectional view taken along a section line XXVII-XXVII of Fig. 17; Fig. 28 15 is a cross-sectional view in a plane passing through a conductive metal member and along a longitudinal direction of the connector of FIG. 15; Figure 29A Fig. 10 is a diagram showing vectors that contribute to total capacitive coupling (capacitive reactance) of the RJ-45 connector at low frequencies - 100 MHz; Figure 29B Fig. 4 is a diagram showing vectors contributing to total capacitive coupling (capacitive reactance) of the RJ-45 connector at high frequencies -2 GHz; Fig. 29C Fig. 3 is an enlarged diagram (100 MHz, zoomed in) showing vector summations for the RJ connector of the invention at low frequencies - 100 MHz; and Fig. 29D Fig. 2 is an enlarged diagram (2 GHz, zoomed in) showing vector summations for the RJ connector of the invention at high frequencies -2 GHz.
DESCRIPTION OF THE PREFERRED EMBODIMENTS Referring to the drawings, FIG. 1 shows an RJ connector, generally designated 10. The plug 10 comprises a main housing part 12 which interacts with a housing cover 16. A latch 14 is connected to an upper surface of the main body 12 and is used to snap the plug 10 into an electrical outlet (socket). A nut 18 provides a receptacle for wires of a cable (not shown) and offers a connection of the cable to the plug 10.
Fig. 2 shows the connector 10 in an exploded view. The main housing part 12 cooperates with the cover 16 to provide an interior to support a printed circuit board (PCB) 40 and a wire guide assembly 30. The wire guide assembly 30 supports and guides connections of the wires of the cable to wire connections. The wire connections are insulation displacement contacts (IDCs), which are inserted (inserted) into the holes of the connection contacts 72-78 of the PCB 40 and are fixed there with a solderless pressure connection. The conductor wires pass through the nut 18, pass through an adjusting screw 32 and pass through an earth spring 34. The wires are through the
CH 714 342 A2
Wire guide assembly 30 guided. The wire guide assembly 30 is then pressed down onto the PCB to connect the wires of the cable to the IDCs.
As can be seen in Figure 2, the wire guide assembly 30 carries the PCB 40. The wire guide assembly also carries a metal piece 36. The metal piece 36 is held in position relative to the PCB 40 and extends downward from a metal piece grounding contact edge 35 and extends into a gap 65 of the PCB 40 between portions of the PCB 40. The gap 65 separates at least some of the wire contacts 71-78. The associated metal piece 36 disconnects at least some of the wire connections that are connected to the wire connection contacts 71-78 of the PCB 40.
Tongue conductors 50 are held in cooperation with a conductor set cover 38 in a conductor set socket 37. The conductor set base 37 holds and positions each of the tongue conductors 50 in a spacing relation to each other and in a position inside the housing 12.
The conductor set base 37 and the conductor set cover 38 are connected to one another in order to position and hold the tongue conductors 50 relative to the PCB 40. The PCB 40 has an underside (level 1) with a series of tongue conductor contact areas 51-58 (FIG. 5). As best seen in FIG. 4, each of the tongue conductors 50 has an upper surface that defines a conductor contact portion 59. The arrangement of the contacts with the conductor contact section 59 of the tongues 50 is such that the conductor contact section 59 is pressed or driven toward the respective tongue conductor contact region 51-58. The wire guide arrangement 30 holds and carries the PCB 40. The tongues 50 each have the associated inserted / pressed section 85 pressed into passages 88 in the conductor set base 37. The tongues 50 are thereby each carried by the ladder set base 37. The wire guide arrangement 30 is in worn contact with the housing parts 12, 16 on the top and the bottom. The rigid housing part 12 sits on the top of the wire guide arrangement 30 and sits on the top of the conductor set cover element 38. The rigid housing part 16 sits on the bottom of the wire guide arrangement 30 and sits on the underside of the conductor set socket 37. The tongue conductors 50 are pressed against the conductor set socket 37 in order to provide a force-biased contact (clamping contact) of each conductor contact region 59 with the respective tongue conductor contact region 51-58. The force-biased contact or clamping contact (also known as biasing force, biasing or preload) is provided by the clamping action, which is provided by the connection of the conductor set base 37, which holds the inserted / pressed section 85, with the conductor set cover element 38. The clamping effect occurs when the PCB 40 and the tongue conductor 50 are pressed together between the housing parts 12, 16. This clamping with the base 37, the cover 38 and the housing parts 12, 16 holds and supports the position of the tongue conductors 50 with a compressive force which is exerted between the individual conductor contact sections 59 of the tongue conductors 50 and the respective tongue conductor contact region 51-58. The conductor contact section 59 of each of the tongues 50 is not elastically deformable and is pressed into physical and electrical contact and in particular a solderless electrical contact with one of the tongue conductor contact regions 51-58 of the PCB 40.
5-12 use the designations 1, 2, 3, 4, 5, 6, 7 and 8 to indicate transmission paths associated with transmission lines. Each transmission line is formed from a pair of transmission paths that can be viewed as having different polarities. The transmission line pair 4, 5 is referred to as the inner pair of an inner transmission line 80, and the pair 3, 6 is referred to as the shared pair of a shared transmission line 90 (see FIG. 13). The peripheral pairs are pairs 1, 2 and 7, 8. The transmission paths are along the connector 10 through the tongue conductors 50, the conductor contact areas 51-58, the through contacts (via holes) 21, 22, 23, 26, 27 and 28 (for the pair 1, 2, for the split pair 3, 6 and for the pair 7, 8), the tracks 41-48, the wire connection contacts 71-78 and the wire connections and wires (not shown).
5-12 show the various layers of conductor material (shielding material) 60, 62 and 64, which form a ground plane, in cross-sectional views of the PCB 40. The conductor material surfaces 60, 62 and 64 are made of interconnected conductor material, as below is discussed in more detail. 5-12 show different levels (levels 1-8) of the PCB 40. The levels include conductor traces or other elements, such as coupling / compensation elements and ground level elements, which are described below. Level 1 is referred to as the bottom or first side surface and level 8 is referred to as the top or second side surface. Level 1 and level 8 can also be internal levels, the level being essentially covered by FR4 or provided with outer layers made of FR4 material. However, level 1 includes the conductor contact areas 51-58, which, in accordance with the embodiment of the connector 10 of FIGS. 1-14, are positioned on an outer surface of the PCB 40, namely on the underside of the PCB 40. The conductor contact areas 51-58 are relative to the tongues 50 positioned to provide the pressure contact as described above.
Fig. 5 shows metallized vias (vias, vias) 21, 22, 23, 26, 27 and 28 used to connect the tongue conductor contact areas 51, 52, 53, 56, 57 and 58 with traces on one of the other levels of PCB 40 are provided. The bottom of the PCB 40 with the tongue contact areas 51-58 includes a first tongue contact area of the split pair 53, a first inner tongue contact area of the inner pair 54, a second tongue contact area of the inner pair 55, and a second tongue contact area of the split pair 56, which are of particular interest ,
On the top (first side) of the PCB 40, a first trace of the inner pair 44 extends from the tongue conductor contact area 54 to the wire connection contact 74. The second trace of the inner pair 45 extends from the tongue conductor contact
CH 714 342 A2 area 55 to wire connection contact 75. The first trace of the inner pair 44 and the second trace of the inner pair 45 are part of the inner transmission line 80 (see FIG. 13). The tracks 47 and 48 also run on level 1 (the underside of the PCB 40) from the respective tongue conductor contact region 57, 58 to the respective wire connection contacts 77 and 78.
A coupling arrangement CA / CA 'is provided very close to the respective tongue conductor contact areas 53, 54, 55 and 56, spaced apart by a distance D, and forms the main coupling M1 together with the coupling to the tongue conductors 50. The coupling arrangement CA / CA 'is used to meet the TIA requirement for a defined coupling M1 in view of the coupling on the conductor tongues. Alternatively, however, the main coupling M1 can be provided wholly or essentially by the conductor tabs 50, such as by providing large tabs 50 that meet the TIA requirement with respect to a specific coupling amount. The coupling arrangement CA / CA 'contains a first coupling CA between the divided pair and the inner pair, which is connected by a coupling section 39 connected by the track 45 to the tongue contact area 55 and by a track 79 and by the via 26 to the tongue contact area 56 Coupling section 49 is formed. This coupling between the transmission paths 5 (of the inner pair) and 6 (of the divided pair) has the same coupling polarity as the polarity of the coupling that occurs between adjacent tongue conductors 50 of the transmission path 5 (of the inner pair) and 6 (of the divided pair). The coupling arrangement CA / CA 'contains a second coupling CA' between the split pair and the inner pair, which is connected by a coupling section 39 'through the track 44 to the tongue contact area 54 and one through a track 79' and through the via 23 with the Tongue conductor contact area 53 connected coupling section 49 'is formed. This coupling between the transmission path 4 (of the inner pair) and the transmission path 3 (of the divided pair) has the same coupling polarity as the polarity of the coupling between adjacent tongue conductors 50 of the transmission path 4 (of the inner pair) and 3 (of the divided pair) occurs. The coupling that occurs between the tongues 50, in particular in the inner pair 4, 5 and in the split pair 3, 6, and the coupling provided by the coupling arrangement CA / CA 'jointly provide the main coupling M1 of the plug 10. This main coupling occurs essentially completely in the area of the tongues 50.
Level 1 also contains a conductive layer 62. The conductive layer runs over a large part of level 1, with the exception of non-conductive areas next to the tracks 44, 45, next to the through holes 21, 22, 23, 26, and 28 and the Tongue conductor contact areas 51, 52, 53, 56, 57 and 58, next to the through holes 68 and 67 and next to the wire connection contacts 71-78. Terminals 71-78 are metallized vias that pass through each of the holes in layers 1-4. 6 and 7, the connection contacts 71-78 (the electrical contacts) are shown at a distance from the conductive material surfaces 60. The area between the large circle (an interruption in the conductive material surfaces 60) and the small circle (the contacts 71-78) is non-electrical, which prevents the pins of the IDCs from being short-circuited to earth. The conductive material surfaces 60 are in electrical communication with the electrical vias 63. The electrical vias (via holes) 63 pass through the PCB 40 and are electrically with conductive material interfaces 60 with conductive material surfaces 62 on the underside of the PCB 40 (FIG. 5) and conductive Material surfaces 64 connected to an upper side of the PCB 40 (FIG. 8). The contact areas 62, 64 at levels 2, 3, 4, 5, 6 and 7 make electrical contacts with the conductive material surfaces 60 and also make electrical contact with the grounding spring 34 to fully earth the PCB 40 and the grounding spring 34 (the ground plane). The conductive material surface 66 can also be applied to the inner facet of the openings 20 and also the inner facet of the gap 65.
Level 2 (FIG. 6) also includes a conductive material interface 60. The PCB 40 may include many such conductive material interfaces 60. In the embodiment shown, six intermediate / internal layers of conductive material 60 are provided between the lower conductive material surface 62 in the upper conductive material surface 62. On level 2 there are also non-conductive areas, for example next to the through holes 21, 22, 23, 26, 27 and and next to the track and negative feedback sections 49. Non-conductive areas are also provided next to the through contacts 68 and 67 and next to the wire connection contacts 71-78 , The conductive electrical vias 63 may be selectively positioned as described below to electrically connect each of the interlayer conductive material surfaces 60 to the other interlayer conductive material surfaces 60 and to the upper and lower conductive material surfaces 62 and 64.
Level 3 (Fig. 7) also includes a conductive interlayer material surface 60 and non-conductive areas. A non-conductive area is provided in particular on the conductive through holes 68 and 67. The conductive through hole 67 is connected to the compensation coupling portion 69 of the sub compensation coupling C via a short track. As can be seen in FIG. 8, level 4 also includes an interlayer conductive material surface 60 with a non-conductive area at conductor vias 68 and 67. Conductive vias 68 are connected to the counter compensation coupling portion 70 in level 4 via a short trace. The coupling section 68 and the negative coupling section 70 form a secondary compensation coupling C, which provides a secondary coupling between the line 4 of the inner pair 4, 5 (FIG. 5) and the line 6 of the divided pair 3, 6 (FIG. 12). This coupling on the secondary compensation coupling C (between the transmission paths 4 and 6) can be viewed as having a different polarity (or opposite polarity) from the main coupling M1 (which is provided between the transmission paths 5 and 6).
CH 714 342 A2 At level 4 (FIG. 8), traces 47 and 48 are connected to through contacts 27 and 28 and run to wire connection contacts 77 and 78, respectively. Level 5 (FIG. 9) also contains a conductive intermediate layer -Material surface 60 with non-conductive areas, which contain non-conductive areas with the tracks 41, 42, which correspond to the lines 1, 2, which are connected to the through contacts 21 and 22 and run to the wire connection contacts 71 and 72, respectively. Level 6 (FIG. 10) also includes a conductive interlayer material surface 60 with non-conductive areas that contain non-conductive areas for the tracks 41, 42. Level 7 (FIG. 11) includes an interlayer conductive material surface 60 with non-conductive areas that correspond to the various conductive vias.
Fig. 12 shows level 8 with a first track of the divided pair 43, which extends from the via 23 to the wire connection contact 73. The other, second track of the split pair 46 extends from the via 26 to the wire connection contact 76. The track of the split pair 46 is connected to the via 68 to connect to the negative feedback section 70 of the secondary coupling C. As noted, the main coupling M1 contains the coupling provided by the coupling arrangement CA / CA 'and the coupling provided by the tongues 50, the entire main coupling M1 occurring in the area of the tongues 50. The secondary compensation coupling C is small in comparison to the main coupling M1, in particular the secondary compensation coupling C is not more than half of the main coupling and, more advantageously, the compensation coupling arrangement C provides an amount of the secondary coupling that is less than 1/1 of an amount of the main coupling M1. The secondary compensation coupling C is arranged at a distance from the tongues 50, in particular it is spaced more than 5 mm from the tongues 50 in the example (see FIG. 7). In particular, the path length distance d to a center of the compensation coupling C is greater than 5 mm and the path length D from the tongue conductor contact areas 53 and 56 (and from the through contacts 23 and 26) to a center point coupling arrangement CA / CA 'is much shorter than d (D »d ).
The PCB 40 contains openings 20. One of the openings 20 provides a separation between, on the one hand, the traces of the inner pair 44, 45 and, on the other hand, the traces 47 and 48. The other of the openings 20 offers a separation between, on the one hand, the traces of the divided pair 43, 46 and on the other hand the tracks 41, 42. On a rear side of the PCB 40 (the wire receiving side), the gap 65 offers a separation between the tracks leading to the connection contacts 71, 72 on the one hand and the connection contacts 77 and 78 on the other hand Metal piece 36 held in the gap. The electrical vias 63 connect each of the various conductive layer material regions 60, and 64. The vias 63 may be patterned to provide additional isolation between the transmission lines and the coupling of the conductive surfaces 60, 62 and 64, and in particular the conductive surfaces 60, 62 and 64 between certain tracks. The vias 63 connecting the conductive surfaces 60, 62 and 64 follow, for example, the conductive material 62 between the paths of the tracks 44 and 45 (FIG. 5). The vias link the conductive material areas between tracks 41 and 42 to the other layers (FIG. 9). The conductive surface 62 between the tracks 43 and 46 is connected to the various other layers 62, 60 by numerous vias 63. Both the position of the vias 63 and the pattern of the conductive surfaces 60 and 62 are used to create the ground plane and to avoid further coupling between the lines.
As can be seen in Fig. 13, the proximity of the conductors 50 of the inner pair 80 transmission line and the divided pair 90 transmission line contributed to the main coupling M1. In particular, since the one or more layers of conductive material surfaces 60, 62 and 64 and the traces of the inner pair 44 and 45 are on one side (on the underside - FIG. 5) of the PCB 40 and the traces of the split pair 43 and 46 On another level (on the top-FIG. 12) of the PCB 40, the transmission signals on the transmission line 80 of the inner pair (4, 5) are not coupled to transmission signals on the transmission line 90 of the divided pair, at least in the area of the PCB 40. The conductive material surfaces 60, 62, and 64 and 66 suppress or remove substantial variation in the dielectric characteristics of the FR4 of the PCB 40 to control and reduce coupling effects. The conductive layer is provided on the inner surface of the opening 20 and also at the gap 65.
The shape of the tongues 50 with the conductor contact section 59 is also particularly advantageous for reducing the coupling in the area of the tongues 50. The tongues each contain a plug contact longitudinal section 84 (which is shown as running horizontally) and an expanded section, inserted / pressed-in section 85 (which is shown as running vertically), which terminates at the conductor contact section 59, which has a contact area which electrically and physically touches the respective tongue conductor contact region 51, 52, 53, 56, 57 or 58. The horizontal section 84 is at an angle (a 90 degree angle) to the vertical plug contact longitudinal section 85. The vertical section 85 is advantageously much shorter than the horizontal section 84. The length of the vertical section 85 only needs to be sufficient long to pass through (and preferably be inserted into) the lead set socket 37 and to provide contact at the contact portion 59. The horizontally extending plug contact section 84 is long enough to provide the plug contact surface of the respective tongues 50 for contact with contact conductors of a receptacle.
The connector 10 may have housing parts 12, 16 made of metal. The conductor set cover 38, the conductor set base 37 and the wire guide arrangement 30 are formed from a suitable plastic such as polycarbonate (PC), polyethylene (PE) or liquid crystal polymer (FKP). The conductive layer material surfaces 60, 62, 64 and 66 are conductive metal layers, such as a copper film or other conductive film or another conductive material layer.
CH 714 342 A2 As noted above, the PCB 40 can be formed from multiple layers. The layers of PCB 40 include at least one layer that forms the top and bottom. The PCB layers with the tracks 41-48 can be FR4 substrate layers (glass-reinforced epoxy laminate sheet layers). One or more FR4 or PC layers can be provided. More than one interlayer conductive surface 60 may be provided, such as layers of conductive material 60 with intervening layers of FR4 or PC. At least one interlayer conductive surface 60, a layer of conductive material such as copper film, is provided between the layer having the upper conductive material surface 64 and the lower conductive material surface 62 of the PCB 40.
The connection of the wire guide assembly 30 to hold and support the PCB 40 supports the connection of the metal piece 36 to the PCB 40. The metal piece 36 has lead pins 33 which lead through the conductive through openings 61 in the PCB 40 and Make electrical and physical contact with them (Fig. 14). The conductive through openings 61 are in electrical contact with the conductor layer surfaces 60 and are connected to the conductor layer surfaces 62 and 64 by vias 63. The conductor pins 33 provide a conductive connection of all conductor layer surfaces 60, electrical vias 63, conductor layer surfaces 62, 64 and the inner faceted conductor layer material of the openings 66 to the metal piece 36. The configuration forms a complete and connected ground plane. The metal piece 36 is elastically deformable and is in electrical contact with the conductive metal housing part 12 at the ground contact edge 35 (FIG. 14). The ground spring 34 contacts the housing 12. The metal piece 36 contacts the conductor layer system of the PCB by touching the conductive layered gap 65 and also based on the two pins 33 in the two electrically conductive through holes 61. This forms the fully connected ground plane. The full ground plane is connected via the ground spring 34 to a ground shield of the cable that carries the wires.
15-28 show a further embodiment of a plug 10 'according to the invention. The same reference numerals are used where the elements in each of the embodiments are very similar or substantially the same. However, the connector 10 'contains several elements that differ from the elements described above with respect to the connector 10. The different elements essentially relate to the aspects relating to the shape and contact of the tongue conductors 50 'and to the slight differences associated therewith at the tongue conductor contact areas 51' -58 'of the PCB 40'.
The connector 10 'also has the main coupling M1 consisting of the coupling arrangement CA / CA' plus the coupling occurring on the tongues 50 '. The main coupling M1 is again physically very close to the tongues 50 '. In particular, the electrical path distance D from the coupling sections (track capacitor areas) 39/39 'and 49/49' of the coupling arrangement CA / CA 'to the tongue conductor contact areas 53, 54, 55 and 56 is very short and in particular much shorter than a transmission path length d of the compensation coupling sections 69 , 70 of the compensation coupling C and the associated tracks from the tongues 50 '. In the example of the plug 10 ', the path length distance d to a center of the compensation coupling C is greater than 5 mm and the path length D from the tongue conductor contact areas 53 and 56 (and from the through contacts 23 and 26) to a center of the coupling arrangement CA / CA' is a lot shorter than d (D »d). The compensation coupling C offers a smaller coupling compared to the main coupling, which consists of the main coupling M1 plus the coupling occurring on the tongues 50 '. In particular, the compensation coupling C is not more than half of the main coupling (which consists of the main coupling M1 plus the coupling occurring on the tongues 50 ').
The connector 10 'has tongues 50', both of which have a press contact of the conductor contact sections 59 ', which contact the tongue conductor contact sections 51' -58 'on the PCB 40'. The tongues 50 'also have integrally formed lead pins 87 in electrical and physical contact with the conductive coating of the conductive vias 21' -28 'on the PCB 40'. The conductive through openings 21 '-28' each receive a tongue pin 87 of the tongues 50 '. As can be seen in FIG. 18, each conductor tongue 50 ′ is pressed or cast into the conductor set base element 37. This will position the connector contact portion 84 '(shown as extending horizontally) and will also hold an inserted / depressed portion 85' (shown as extending vertically). The horizontally extending longitudinal connector contact section 84 'is at an angle (a 90 degree angle) to the vertically extending section 85'. Each tab 50 'includes the lead contact portion 59' and the tab contact areas 51 '-58' on the PCB 40 'and each tab 50' includes a lead pin 87 which is in one of the conductive vias 21 ', 22', 23 ', 24', 25 ', 26', 27 'and 28' is added. This offers improved electrical contact. 29A-D show vector summations for the RJ plugs 10 and 10 'of the invention. This shows a reduced difference in total capacitance couplings at low frequency and at high frequency, so that the difference is more linearly proportional to frequency. In FIGS. 29A-D, the main coupling M1 consists of the coupling of the tongues 50 and is indicated by Vb1 and optionally also (in order to meet the requirement of a specific coupling amount of the TIA standard) also consists of the coupling arrangement CA / CA 'and is by Vb2 is displayed and is displayed together with M1 by coupling Vb. The additional coupling of the small compensation capacitor (secondary compensation coupling) C is shown at Vc. Fig. 29A shows the vector Vb with the component vectors Vb1 and Vb2 and the vector Vc at a frequency of 100 MHz. Fig. 29C shows in an enlarged view the vector summation at a frequency of 100 MHz the vector summation Vb = Vb1 + Vb2 in the upper section and also shows the vector with opposite polarity Vc. In the lower portion of Fig. 29C, the vector summation V = Vb + Vc is shown at a frequency of 100 MHz. Fig. 29B shows the vector Vb with the component vectors Vb1 and Vb2 and the vector Vc with one
CH 714 342 A2
Frequency of 2 GHz. Fig. 29D shows in an enlarged view the vector summation at a frequency of 2 GHz the vector summation Vb = Vb1 + Vb2 in the upper section and also shows the vector with opposite polarity Vc. In the lower portion of Fig. 29D, the vector summation V = Vb + Vc at a frequency of 2 GHz is shown. The total coupling (the capacitive reactance) V = Vb + Vc is similar for the frequency of 100 MHz and for the frequency of 2 GHz. The change V = 1.80 at 100 MHz and V = 1.82 at 2 GHz is more linearly proportional to the frequency change in this configuration, which contains a secondary compensation coupling C indicated at Vc.
While specific embodiments of the invention have been shown and described in detail to illustrate the application of the principles of the invention, it will be appreciated that the invention can be practiced otherwise without departing from these principles.

权利要求:
Claims (10)
[1]
claims
1. RJ-45 connector (10) for high frequency applications, the connector comprising:
a housing (12, 16);
a plurality of contact lead tabs (50);
Insulation displacement contacts (71-78);
a printed circuit board (40) with a plurality of transmission paths (41-48) connecting corresponding tongues and insulation displacement contacts, wherein:
the plug (10) has a main capacitive coupling (M1) which comprises a capacitive coupling between immediately adjacent contact conductor tabs (50) and corresponding connected circuit parts of the PCB (40); the PCB further comprises a compensation coupling arrangement (C) which offers a smaller coupling compared to the main coupling (M1);
the compensation coupling (C) is at most half of the main coupling (M1) and has a different polarity from the main coupling;
the compensation coupling (C) is connected (71-78) to a set of transmission paths (44/67, 46/68) at a position between the main coupling (M1) and the insulation displacement contacts.
[2]
2. Plug (10) according to claim 1, wherein an amount of the compensation coupling arrangement (C) is less than 1/10 of an amount of the main coupling (M1).
[3]
3. Plug (10) according to claim 2, wherein the compensation coupling arrangement (C) is electrically connected to the contact conductor tongue (50) at a path distance from the contact conductor tongues (50) which is greater than 5 mm.
[4]
4. RJ-45 connector (10) for high-frequency applications according to claim 1, wherein corresponding connected circuit parts of the PCB (40) further comprise a coupling arrangement (CA / CA) in addition to the plurality of contact conductor tongues (50) and the coupling arrangement (CA / CA ' ) forms the main capacitive coupling (M1).
[5]
5. The connector (10) of claim 4, wherein:
the PCB (40) has a plurality of tongue conductor contact areas (51-58 / 5Γ-58) which connect respective contact conductor tongues (50) to the respective transmission paths (41-48) associated therewith;
the contact conductor tabs (50) comprise an inner pair of conductor tabs arranged side by side and in electrical contact with an inner pair of tongue conductor contact regions (54, 55) of the plurality of tongue conductor contact regions (51-58 / 51 '-58');
the contact tabs (50) further comprise a split pair of tabs, each split pair of tabs adjacent to a respective one of the inner pair of tabs and in electrical contact with a split pair of tab contact areas (53, 56) of the plurality of tab contact areas (51-58 / 51 '-58') is arranged;
the coupling arrangement (CA / CA ') comprises a first coupling section from a split pair to an inner pair (39, CA) which is provided on the PCB (40) and is electrically connected to one of the inner pair of tongue conductor contact areas (55) and is electrically connected to the adjacent, split pair of tongue conductor contact areas (56) providing capacitive coupling therebetween;
the coupling arrangement (CA / CA ') further comprises a second coupling section from a split pair to an inner pair (39', CA ') which is provided on the PCB (40) and is electrically connected to another of the inner pair of tongue contact areas (54 ) is connected and electrically connected to the adjacent, split pair of tongue conductor contact areas (53), providing capacitive coupling therebetween; the first coupling portion from a split pair to an inner pair (39, CA) is connected to one of the inner pair of reed contact areas (55) and the adjacent pair of reed contact areas (56) are spaced D apart therefrom;
the second coupling portion is connected from a split pair to an inner pair (39 ', CA ’) with the other of the inner pair of tongue conductor contact areas (54) and the adjacent pair of tongue conductor contact areas (53) are spaced D apart therefrom;
the compensation coupling arrangement (C) comprises a compensation coupling section from the divided pair to the inner pair, which is electrically connected to one of the tracks (44) connected to one of the inner pair of tongue conductor contact areas (54) and electrically to one of the ones to the adjacent, shared one pair
CH 714 342 A2 is connected by tongue conductor contact areas (56) connected tracks (46) which is adjacent to one of the tracks (44) connected to one of the inner pair of tongue conductor contact areas (54), thereby providing capacitive coupling therebetween;
the compensation coupling arrangement (C) is spaced d along the associated track from the compensation coupling arrangement (C) to the conductor contact areas (51-58 / 51 '-58'); and d »D.
[6]
6. The connector (10) of claim 1, wherein:
the PCB (40) has a plurality of tongue conductor contact areas (51-58 / 5Γ-58); connect the respective contact conductor tongues (50) to the respective transmission paths (41-48) associated therewith;
each tongue conductor (50) comprises a longitudinal connector contact section (84, 84 ') with a tongue contact length for contact with contact conductors of a receptacle and an elongated section (85, 85') which is at an angle relative to the longitudinal connector contact section (84, 84 '); and the elongated section (85, 85 ') terminates at a conductor contact section (59, 59') which has a contact area which electrically and physically contacts the respective tongue conductor contact region (51-58 / 51 '-58').
[7]
7. The connector (10) according to claim 6, wherein the housing (12, 16) comprises one or more housing parts which carry the plurality of contact conductor tongues (50) and carry the PCB (40) and the contact conductor tongues (50) and the PCB ( 40) to force the conductor contact portion (59, 59 ') of each of the plurality of conductor contact tongues (50) into contact with the associated one of the conductor contact areas (51-58) of the PCB (40) to provide solderless electrical and physical Provide connection between each of the contact tabs (50) and a corresponding one of the transmission path tongue contact areas (51-58).
[8]
8. The connector (10) of claim 6, wherein:
the housing (12, 16) comprises one or more housing parts which carry the plurality of contact conductor tongues (50) and carry the PCB (40);
each of the contact tabs (50) includes a lead pin (87) integral with the elongated portion (85 '); and each of the conductor contact regions (51 '-58') comprise metallized through openings of the PCB (40) which receive one of the conductor pins (87) in order to make electrical contact between the conductor contact region (51 '-58') and the associated contact conductor tongue (50) provide.
[9]
9. The connector (10) according to claim 8, wherein the conductor pins (87) received in the metallized through openings (51 '-58') insert the respective contact conductor tongue (50) into the PCB.
[10]
10. The connector (10) according to claim 1, wherein the housing (12, 14) comprises one or more housing parts which carry a plurality of contact conductor tongues (50) and carry the PCB (40).

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同族专利:

公开号 | 公开日

AT520584A3|2019-10-15|

AT520584A2|2019-05-15|

CN109787048B|2020-04-03|

TW201924164A|2019-06-16|

US10135195B1|2018-11-20|

AU2018260871A1|2019-05-30|

GB2569869B|2020-04-22|

GB2569869A|2019-07-03|

AT520584B1|2020-12-15|

BR102018073389A2|2019-06-18|

DE102018219315A1|2019-05-16|

SE542621C2|2020-06-16|

TWI673923B|2019-10-01|

CN109787048A|2019-05-21|

FR3073680A1|2019-05-17|

SE1851403A1|2019-05-14|

GB201818166D0|2018-12-19|

FR3073680B1|2021-12-17|

引用文献:

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法律状态:

优先权:

申请号 | 申请日 | 专利标题

US15/810,538|US10135195B1|2017-11-13|2017-11-13|RJ-45 plug for high frequency applications|

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