KR100591231B1 - Connector for electrical isolation in a condensed area - Google Patents

Abstract

The connector module has a header connector and a socket connector. The header connector has an L-shaped ground pin and a signal pin, and the socket connector has an L-shaped ground receptacle connection and a signal receptacle connection. The ground pin engages with the ground receptacle connection at the L-shaped end to generate force in the first and second directions, the two directions being perpendicular to each other. The signal pin engages the signal receptacle connection at the L-shaped end with two directions opposite to the first and second directions, respectively. Therefore, the forces in the first and third directions are generally arranged to face each other and preferably cancel each other, and the forces in the second and fourth directions are also generally arranged to face each other and preferably cancel each other. The ground receptacle connection and the signal receptacle connection are arranged in a mirror relationship to improve signal completeness to eliminate crosstalk.

Description

Connector for electrical insulation in dense areas {CONNECTOR FOR ELECTRICAL ISOLATION IN A CONDENSED AREA}

This application is part of application No. 08 / 942,084, filed Oct. 1, 1997.

The present invention relates generally to electrical connectors. In particular, the present invention relates to an electrical connector having a dense connection member capable of transmitting signals without crosstalk between adjacent connection members.

In electronic devices, there is a need for electrical connectors that connect in the signal path, which is often dense and causes problems due to interference between signals transmitted along adjacent paths.

In order to minimize such a problem, a method of providing a ground connection to a connector is known, which serves to effectively remove undesirable interference between signal paths.

However, grounding alone is not always sufficient, especially for connectors in which the connectors constituting the signal path through the connector extend at sharp angles, so grounding alone is not sufficient because interference between adjacent signal paths is particularly problematic. not.

In many cases where electrical signals are transmitted between auxiliary assemblies of complex electrical and electronic devices, reducing the size is very helpful for the usability or convenience of the device. For that purpose, cables comprising very small conductors are now obtainable and it is practical to fabricate pads that are precisely placed on a circuit board or the like and spaced at very close spacing. It is therefore desirable to make a reduced size connector that connects the cable and the circuit board to a repeatable, easy, reliable, minimally adverse effect on the electrical signal transmission of the circuit comprising the connector.

In high speed backside applications, it is desirable that the crosstalk between signal currents passing through the connector is small. It is also desirable to maximize signal density. Less crosstalk results in better signal quality. Higher densities can increase the number of circuits that pass through the connector.

Typically, pinned and receptacle connectors are used to create disconnectable and electrically reliable interfaces. Furthermore, providing two additional one-sided support points at the connection point further increases reliability. In the prior art, two receptacle one side support beams were generally placed on opposite sides of the protruding pin or blade. This 180 ㅀ " opposite beam " method requires a significant amount of engagement clearance in the face formed by the curvature of the unilateral support beam during engagement. In addition, due to fabrication tolerances are angled outwards from the central longitudinal axis of the engagement pin or blade to prevent stubbing during the initial engagement. The gaps for spring beam bending and catching projections require a connection gap in the "bending plane". This gap must be accommodated in the connector receptacle housing, which is an important limiting factor in improving connector density.

It is desirable to insulate both the vertical and horizontal planes along the entire connector signal path (including coupling zones) to minimize crosstalk through the coaxial isolation of the signal current passing through the connector. The gap conditions conflict with the requirements for vertical and horizontal electrical insulation in opposing unilateral support beam bending planes while simultaneously maintaining or increasing the connector density.

A method for achieving electrical isolation using an "L-shaped" ground connection structure is described in US Pat. No. 5,660,551 to Sakurai, the disclosure of which is referred to in this patent. Along the length of the socket connector, the Sakurai patent created an L-shape in the cross section of the ground connection body. In the connection coupling means zone, the Sakurai patent transitions to a flat conventional double unilateral support beam receptacle ground connection and relies on a 90 ° rotated planar blade to create an L-shaped cross section when the blade and receptacle are engaged. The transition of this L-shaped structure in the connection coupling portion is limited in density due to the curved plane gap described above with respect to the signal and ground double beam connections, and also has the potential to create a gap portion where full coaxial insulation cannot be maintained. Moreover, in the Sakurai patent all four unilateral support beam curved planes are oriented in parallel to limit the density.

One conventional method of transmitting data along a transmission line is a common mode method, also referred to as a single end. The common mode relates to a transmission mode for transmitting a signal related to a voltage, and grounding is preferably common to other signals of a connector or transmission line. Another conventional method of transmitting data along a transmission line is the differential mode method. Differential mode relates to a method in which a signal on one line of voltage V transmits the excitation voltage -V. The resulting voltage is V-(-V) or 2V.

The limitation of common mode signal transmission is that some noise on the line is transmitted with the signal. This common mode noise is very often caused by the so-called ground bounce, which is the instability of the voltage level of the common reference plane. In order to reduce the noise of the signal transmission, the signal must be transmitted differentially. In differential receivers, all common mode noise is canceled out. This phenomenon is called common mode noise cancellation and is an important advantage of differential signal transmission.

Since the shield member is inserted between the connection columns in the connector at ground potential, it is generally column-based to install differential pairings at high speed right angle rear connectors. In other words, in order to improve the signal quality, the prior art generally uses a pair design based on columns found in VHDM or the like manufactured by Teradyne Corporation of Boston, Massachusetts. In column-based pairing, skew is introduced between the true voltage and the excitation voltage of the differential pair. One of the signal pairs will arrive faster than the other. This difference in arrival time reduces the efficiency of common mode noise cancellation in the differential mode and slows the output rise time of the differential signal. Therefore, data throughput is reduced by column-based pairing because the bandwidth, which is a measure of how much data is passed through the transmission line structure, is inversely proportional to the rise time (bandwidth = 0.35 / rise time).

Although electrical connectors have been very developed, there are inherent problems with this technique, particularly with densely dense connection members while preventing crosstalk between adjacent connection members. Therefore, there is a need for an electrical connector that occupies a small area while maintaining signal quality.

It is an object of the present invention to provide a connector module having a tightly dense connection member and preventing crosstalk between the connection members to maintain signal quality.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a connector mounted on a circuit board, comprising: a connector module comprising a housing, a header connector supported by the housing and comprising a ground pin and a signal pin, and a socket connector comprising a ground receptacle connection and a signal receptacle connection. Wherein the ground pin is engaged with the ground receptacle connection to generate a force in the first and second directions, the signal pin is engaged with the signal receptacle connection to generate a force in the third and fourth directions, and the first and third directions Are opposite to each other, and the forces in the second and fourth directions are opposite to each other.

In another embodiment within the scope of the invention, the first and second directions are perpendicular to each other, and the third and fourth directions are also perpendicular to each other.

According to another feature of the invention, the cross section of the ground pin is L-shaped and has two sides at the end of the L-shaped, the cross-sectional L-shaped cross section of the ground receptacle connection, the L-shaped cross section of the signal receptacle connection, and the ground pin is L-shaped Engage with the ground receptacle connection on the side. In addition, the cross section of the signal pin is rectangular and engages with the signal receptacle connection on two adjacent sides.

In other embodiments within the scope of the present invention, the signal pins are positioned diagonal to the ground pin.

In another embodiment within the scope of the present invention, the ground receptacle connection and the signal receptacle connection are 90 degree offset double beam connections and the ground receptacle connection is disposed in an inverted direction with respect to the signal receptacle connection.

In another embodiment of the present invention, a connector mounted on a circuit board includes a connector module including a housing, a connector module supported by the housing, a header connector including a ground terminal having a plurality of pins, and a signal pin; And a socket connector comprising a ground receptacle connection and a signal receptacle connection. The ground terminal has two pins, the cross section of each of the two pins is L-shaped, each of the L-shaped cross-section pins has two sides at the L-shaped end, and the ground terminal is formed of one L of the L-shaped cross-section pins. The two sides engage the ground receptacle connection to generate a force in the first and second directions, and the signal pin engages the signal receptacle connection to generate a force in the third and fourth directions, the forces in the first and third directions being mutually Face each other, and the forces in the second and fourth directions also face each other.

According to another feature of the invention, the ground terminal comprises a first connection portion and a second connection portion, the first connection portion is coupled to the second connection portion, and a plurality of pins are provided on the second connection portion. Further, each of the first and second connecting portions has a plurality of protrusions and ridges, and the protrusions and ridges cooperate with each other to couple the first connecting portion to the second connecting portion. Also, the two pins are located in mirror symmetrical relationship.

According to another feature of the invention, the signal pin is located diagonally to the ground terminal. The header connector also includes a second signal pin positioned diagonally to the ground terminal. The socket connector also includes a second ground receptacle connection and a second signal receptacle connection. One of the two pins of the ground terminal is coupled with the first ground receptacle connection, the other of the two pins of the ground terminal is coupled with the second ground receptacle connection, the signal pin is coupled with the signal receptacle connection, and the second signal The pin engages with the second signal receptacle connection. The two pins are arranged mirror-symmetrically, the second ground receptacle connection is disposed mirror-symmetrically with respect to the ground receptacle connection, and the second signal receptacle connection is disposed mirror-symmetrically with respect to the signal receptacle connection. The ground terminal has a tail, and the connector module also includes a second ground terminal that electrically connects with the tail of the ground terminal.

In another embodiment within the scope of the present invention, the electrical interconnection comprises a header connector having first signal pins and second ground pins arranged generally rectangularly, the pins being offset diagonally relative to each other; A third signal receptacle terminal arranged to mate with a first signal pin and generally arranged in a rectangular shape, and a fourth ground receptacle terminal arranged to mate with the second ground pin and arranged in a generally rectangular shape, wherein the third and fourth The receptacle terminal is a receptacle connector that is diagonally offset from each other and offset from each other, and one applies a generally transverse connecting force to the connecting pin in the first direction and the other on the pin in the second direction perpendicular to the first direction. A signal receptacle terminal comprising a pair of connection elements exerting a connecting force, and a ground including a pair of connection terminals A ground receptacle terminal for applying a connecting force in a transverse direction to the mating pins in the opposite direction and parallel to the first direction and the other ground receptacle connecting terminal to a mating force in the opposite and opposite mating pins in the second direction. It includes. The first force of the connecting force on the signal pin and the second force of the connecting force on the ground pin are generally equal in magnitude and opposite in direction. The first and second force are collinear along the diagonal direction.

The foregoing features of the present invention will become more apparent from the following description with reference to the accompanying drawings.

The present invention relates to an electrical connector module having a compact shape that provides coaxial electrical insulation of a signal connector. The present invention insulates the connections in the horizontal and vertical planes so that signal isolation is achieved within the connection coupling portions to a minimum size.

1 is a partial side view of a first embodiment of a high speed transmission connector according to the present invention, in which parts are separated. The straight part of the header connector 10 is comprised by the header housing 12, the pin (male connection part) 15 for signal transmission lines, and the pin (male connection part) 17 for ground lines. These pins 15 and 17 may be arranged in multiple rows on the header housing 12 of the coupled housing 10. The housing is preferably molded using a plastic material such as a high temperature thermoplastic resin. These fins are preferably formed or stamped of phosphor bronze or beryllium copper. Header connector 10 may be mounted or coupled on a first printed card called a motherboard. The right angle part of the socket connector 50 is comprised from the socket housing 52, the signal receptacle connection part 55 for signal transmission lines, and the ground receptacle connection part 57 for ground lines. A plurality of rows of the connections 55 and 57 are regularly arranged to correspond with the connections of the header connector 10. The socket connector 50 may be mounted or connected on a second print card called a daughter board. The housing 52 is preferably molded from a plastic material such as a high temperature thermoplastic resin. The connection is preferably formed and stamped of beryllium copper or phosphor bronze.

FIG. 2A is a cross sectional view of the connector of FIG. 1 with the components assembled; FIG. Multiple connectors in FIG. 2A may be arranged in housing 1 as shown in FIG. 2B. The housing 1 is preferably formed of an electrically insulating material and includes a header housing 3 having an arrangement of the header connector 10 and a socket housing 5 having an arrangement of the socket connector 50.

3 shows a perspective view of an exemplary connector module according to the present invention. In the perspective view of Fig. 3, the parts are separated. The header connector includes a signal pin 15 and a ground pin 17. 4 is a perspective view of an exemplary ground pin in accordance with the present invention. The cross section of the ground pin 17 is preferably L-shaped, and the ground pin preferably extends from the base of the header connector. The ground pin 17 preferably has a plate 16 protruding from the side portion of the ground pin 17. This plate 16 provides insulation and shielding to the header connector. The L-shape is effective in terms of material and increases the bending stiffness. 5 is a perspective view of an exemplary signal pin in accordance with the present invention. The signal pin 15 is also provided on the base of the header connector. The ground pin 17 is preferably located diagonal to the signal pin 15.

The socket connector includes a signal receptacle connection 55 and a ground receptacle connection 57. Preferably, the receptacle connections 55 and 57 are a 90 dB offset dual beam signal receptacle connection and a 90 dB offset dual beam ground receptacle connection, respectively.

6A and 6B are perspective views of exemplary signal receptacle connections in accordance with the present invention. The signal receptacle connecting portion 55 preferably has an L-shaped structure 48 having two connection points 45 and 47 to connect with the signal pin 15. On the front end of the signal receptacle connection 55 of the socket connector a portion 51 is provided which can engage with the mated pin of the header connector, and on the middle part a right angle 54 with a square cross section is provided and fixed. On the end or the rear end, terminals 53 are provided, respectively.

7A and 7B are perspective views of exemplary ground receptacle connections in accordance with the present invention. The ground receptacle connecting portion 57 is preferably L-shaped to accommodate an L-shaped pin (for example, the ground pin 17). Two connection points 70 and 72 are provided to connect with the L-shaped pins. Shaped or perforated portions 59 and 60 of ground receptacle connection 57 are also shown. Right angle shield tab 80 is provided on ground receptacle connection 57 to provide electromagnetic shielding. On the front end of the ground receptacle connection 57 of the socket connector a portion 81 is provided which can engage with the combined pin of the header connector, and on the middle portion a right angle portion 82 having a square cross section is provided and fixed. On the end or the rear end, terminals 83 are provided respectively.

8A and 8B are perspective views of a pair of exemplary socket connectors in accordance with the present invention. 8A and 8B combine the pair of ground receptacle connections 57 of FIGS. 7A and 7B with the pair of signal receptacle connections 55 of FIGS. 6A and 6B. Pins 15 and 17 of FIGS. 4 and 5 are also shown.

By coupling the header connector 10 and the socket connector 50 together, the motherboard is connected to the daughter board. Ground pin 17 and signal pin 15 couple receptacle connections 57 and signal receptacle connections 55 at connection points 70, 72, 45, and 47, respectively, so that other signals within the connector module in the connection coupling zone. Electrical insulation is provided in a diagonal direction with respect to the connection.

9 shows a cross-sectional view of an exemplary connector module in accordance with the present invention. For signal receptacle connections 55, connection points 45 and 47 engage on adjacent sides 22 and 24 of signal pin 15, rather than on opposite sides of signal pin 15, which are preferably rectangular in cross section. For ground receptacle connection 57, connection points 70 and 72 engage on L-shaped ends 18 and 20 of L-shaped ground pin 17. The coupling form provides more space to surround the signal with ground. The signal is transmitted from the ground of the header connector to the socket connector on one pin (i.e., L-shaped ground pin 17) to provide two connection points. This electrically insulates the dense space.

Multiple rows and columns of connections of the connector module may be arranged regularly in a dense arrangement. The preferred pitch is 2 mm and it is preferred that the signal connection column is inserted between two adjacently located ground connection columns. 10A illustrates an arrangement of four exemplary connector modules in accordance with the present invention. Each signal pin 15 is shielded by the ground receptacle connection 57 in the connector module as well as the ground receptacle connection 57 in the adjacent module. Although four connector modules are shown in FIG. 10A, other number of connector modules may be arranged.

The moment of inertia of the L-shaped pins during the bending operation is much greater than with conventional blades. Therefore, the L-shaped cross section of the ground pin 17 increases the overall bending stiffness of the pin cross-sectional area, which is mechanically advantageous over blade shapes of similar thickness, where the bending stiffness is the product of the Young's modulus (E) and the moment of inertia (I). . This stiffness is important in order to reduce the likelihood of the pin deforming during engagement. Stiffness increases more efficiently when using L-shaped pins than square or circular cross sections of similar thickness.

Exemplary embodiments allow the orientation gap of the curved plane to be more dense. Further, the " lateral " 90 dB beam coupling of the ground receptacle connection 57 is preferably arranged in an inverted direction with respect to the signal receptacle connection 55. In other words, the offset direction of the signal receptacle connection 55 is opposite to that of the ground receptacle connection 57. The tight 90 kHz opposing signal and ground beam shape of the present invention aids in balanced reaction forces. The inverted directions are generally opposed to each other and are preferably arranged to cancel each other rather than accumulate and generate connection coupling reaction forces emerging from the signal and ground receptacle connections 55 and 57. Increasing the reaction force in one direction during mating of the connector has the potential to generate undesirable "twist" or torque that can damage the printed circuit board. The present invention preferably has two beams or connection points in a first curved plane, for example a vertical curve plane, and preferably has two different beams or connection point curves in a second curved plane, for example, a horizontal curve plane. . In other words, one of the two connection points 70 and 72 bends in the first direction, and the other connection points 70 and 72 bend in the second direction, which is preferably perpendicular to the first direction. In addition, one of the two connection points 45 and 47 bends in the third direction, and the other connection points 45 and 47 bend in the fourth direction. The third direction is opposite to the first direction and the fourth direction is opposite to the second direction. Therefore, the forces in the first and third directions are generally arranged to face each other and preferably cancel each other, and the forces in the second and fourth directions are generally arranged to face each other and preferably cancel each other. Therefore, reaction force is minimized.

In particular, the connector module according to the present invention can achieve a force balance as shown in the free object diagram of FIG. 10B. The ground receptacle connection 57 is connected to the ground pin 17 to generate a first force, represented by the vectors FH1 and FV1 in the horizontal and vertical directions, respectively. The force acts on and engages the connector module, preferably generating a first force which is diagonal to the connection 57 and represented by the vector FD1. Another force is generated by the signal receptacle connection 55 on the signal pin 15 to generate a second force, represented by the vectors FH2 and FV2 in the horizontal and vertical directions, respectively. The force acts on and engages on the connector module to generate a second force, preferably diagonal to the connection 55 and represented by the vector FD2. Force is generated as a result of the interaction of the ground and signal contacts with the ground and signal pins. Preferably, the vectors FD1 and FD2 are diagonally opposite and have the same size to offset each other and consequently to balance the connector. For example, one vector points in the northwest direction and the other vector points in the southeast direction. Therefore, the present invention combines ground and signal pins with ground and signal connections to balance the forces. These vectors are preferably balanced against each other in the diagonal direction.

11 illustrates an exemplary socket housing in accordance with the present invention. The receptacle socket housing 152 is preferably made of plastic and covers the signal receptacle connection and the ground receptacle connection. Windows 155 and 157 are provided to receive the signal and ground pins from the header connector, respectively.

12 illustrates a cross-sectional view of an exemplary connector module with a receptacle socket housing in accordance with the present invention. FIG. 12 is similar to FIG. 9 and includes elements similar to those described above with respect to FIG. These elements are denoted identically and description thereof is omitted. Signal pin 15 is supported on two sides 26 and 28 by side walls 126 and 128 of receptacle socket housing 152, respectively. Forces are generated by the housing 152 to balance the structure and reduce the undesirable impact of accumulated forces. Due to the connection with the sidewalls 126 and 128, it is possible to use a small signal pin while avoiding undesirable kinks or torques in the connector while maintaining a balanced reaction force.

According to a second embodiment according to the present invention, there is provided a high performance back connector system that can be used for differential pair electrical signal transmission. In addition, row-based pairing is installed. A mirror structure between adjacent connector columns is described where column-based differential pair alignment between adjacent columns of signal pins is achieved. Column-based differential pairing is desirable for connectors because it does not cause signal distortion time problems as in column-based pairing. The true signal and the excitation signal of the column base differential pair are generally transmitted over the same electrical length through the thermal connector, so there is no distortion problem, so there is no distortion. Using differential pairs improves signal density and therefore cancels interference. High speed signals can be used without causing crosstalk. In addition, thermal base pairing eliminates the need for distortion compensation in the substrate design.

In a second embodiment of the present invention, preferably, two header connector ground pins are joined to combine a tail portion for connecting to a printed circuit board, and a corresponding socket connector ground connection, preferably a L-shaped double ground connection coupling pin. It includes. The header ground connection system allows the signal path-to-ground path to be connected to the printed circuit board one-to-one with respect to the mirrored column differential pair approach in such a way that the number of ground through holes on the board is reduced while achieving vertical and horizontal signal shielding. Improve the routeability of printed circuit board traces. Since the ground and signal connections are arranged in paired mirrored relationship, the number of ground pins used is preferably reduced in half.

A second embodiment of the connector according to the invention is shown in partial perspective view in Fig. 13A. The straight portion of the header connector 310 is composed of a header housing 312, a pin (male connection) 315 for a signal transmission line, and a pin (male connection) 317 for a ground line. These pins 315 and 317 are regularly arranged in a number of rows on the header housing 312 of the coupled connector 310. The housing is preferably molded using a plastic material such as a high temperature thermoplastic resin. The pin is preferably stamped and formed using a material such as phosphor bronze or beryllium copper. The header connector 310 may be mounted or connected on a first print card which is a motherboard. The right angled portion of the socket connector 350 includes the socket housing 352, the signal receptacle connection 355 for the signal transmission line (shown in FIG. 16A similarly to the connection 55 of the first embodiment), and the ground for the ground wire. It consists of a receptacle connection 357 (shown in Fig. 16B similarly to the connection 57 of the first embodiment). Multiple rows of connections 355 and 357 are arranged regularly to correspond to the rows of header connector 310. The socket connector 350 may be mounted or connected on a second print card which is a daughter board. The housing 352 is preferably molded using a high temperature thermoplastic resin. The connection is preferably stamped and formed of beryllium copper or phosphor bronze.

13B shows a preferred arrangement of pins 315 and 317 in the header housing 312. 13B shows a portion of the pins 315 and 317 that are inserted into the motherboard, for example, rather than the connections 355 and 357. There is one row of ground pins 317 for every two rows of signal pins 315. This is due to the mirror pair relationship of the connector to be described below. Also shown in FIG. 13B are portions 510 and 520 of ground pin 317. These portions 510 and 520 are shown in greater detail in Figures 15A and 15B. Since only one row of ground pins 317 are used for every two rows of signal pins 315, the number of ground through holes is reduced, resulting in a less complex and much more easily traceable module. In addition, the signal pin 315 extends away from the header housing 312 at a first distance, and the ground pin 317 extends from the header housing 312 at a second distance shorter than the first distance.

Figure 13C shows in detail the preferred arrangement of the ground pins and signal pins of the connector of Figure 13A. 13C shows a portion of pins 315 and 317 inserted into connections 355 and 357. Also shown in FIG. 13C are L-shaped pins 525 and 530 of ground pin 317. Each pin 525 and 530 is plugged into a coupled ground receptacle connection 357. As shown, the pins 525 and 530 are disposed in mirrored pair relationship, and pins 525 and 530 are provided from one ground pin 317 as shown in FIGS. 15A and 15B to make the circuit less complex. do.

Figure 14 is a perspective view of the connector of Figure 13A with parts assembled. Multiple connectors in FIG. 14 may be arranged in a housing in an arrangement pattern similar to that shown in FIG.

As noted above, Figure 3 shows a perspective view of an exemplary connector module in accordance with the present invention. Note that only the L-shaped end of ground pin 317 is shown in FIG. 3 as element 17. This portion corresponds to, for example, portion 530 of Figure 15A.

FIG. 15A is a perspective view of an exemplary grounding pin of this embodiment in accordance with the present invention with parts removed, and FIG. 15B is a perspective view of the pin of FIG. 15A with the parts assembled; Although the ground pin 317 is preferably a two piece system composed of the first connector 510 and the second connector 520, the ground pin 317 may be formed in one piece or two or more pieces. . As shown in detail in FIG. 15C, the connection 510 has a notch 512 with a protrusion 513. Each protrusion 513 preferably has a ridge or bump 514. The connection 520 has a notch 522 having a protrusion 523. Each protrusion 523 preferably has a ridge or bump 514. The connections 510 and 520 are preferably joined by the cooperation of protrusions and bumps 513, 514, 523 and 524 as shown in Figure 15B. The bump 514 connects with the portion 526 of the connecting portion 520 while the bump 524 is connecting with the portion of the plate 517 of the connecting portion 510.

The connection 510 has a tail 515 extending from the base of the header connector to the motherboard and, for example, the plate 517. The connecting portion 520 preferably has two pins 525 and 530 having an L-shaped cross section from the connecting portion 520 and two plates 527 and 532 protruding from the sides of the pins 525 and 530. It should be noted that the connection may consist of only one pin having an L cross section or two or more pins having an L cross section. L-shaped pins 525 and 530 are plugged into coupled ground receptacle connections, respectively. Because of the double L-shaped pins 525 and 530, the ground connection of the two socket connectors can be connected with the respective header connector ground pins to reduce the number of ground pins in half. Preferably, the two plates 527 and 532 are coplanar. These plates 517, 527, and 532 provide insulation and shielding at the header connectors. The L-shape is efficient in terms of material and increases bending stiffness.

The signal pin 315 of this embodiment is the same as the signal pin 15 described above with respect to FIG. Each L-shaped pin of the ground pin 317 is preferably located in a diagonal direction with respect to the signal pin 315.

As in the first embodiment, the socket connector consists of a signal receptacle 355 and a ground receptacle connection 357. This connecting portion is similar to the connecting portions 55 and 57 of the first embodiment. Receptacle connections 355 and 357 are preferably 90 Hz offset dual beam signal receptacle connections and 90 Hz offset dual beam ground receptacle connections, respectively.

Figure 16A is a perspective view of a pair of exemplary signal receptacle connections 355 in mirror relationship in accordance with the present invention. 16B is a perspective view of a pair of exemplary ground receptacle connections 357 in mirror relationship in accordance with the present invention. Multiple pairs of connections are arranged in rows and columns of connectors to provide horizontal and vertical shielding. Fig. 16C is a perspective view of exemplary socket connectors arranged in specular relationship and six pairs in accordance with the present invention; The present invention provides heat based pairing. Therefore, there is no pair distortion. This reduces electrical time problems and crosstalk.

17A and 17B are perspective views of two pairs of exemplary socket connectors in accordance with the present invention. 17A and 17B combine the signal receptacle connection 355 of FIG. 16A and the ground receptacle connection 357 of FIG. 16B. L-shaped ground pins 575 and 580 and signal pins 315 are also shown. Ground pins 575 and 580 are L-shaped portions disposed in a mirror relationship. L-shaped ground pins 575 and 580 may be coupled to the same ground pin similar to L-shaped pins 525 and 530 of ground pin 317 shown in FIG. 15A. On the other hand, L-shaped ground pins 575 and 580 may be coupled to separate or other ground pins, such as ground pin 17 shown in FIG.

By coupling the header connector 310 and the socket connector 350 together, the motherboard is coupled to the daughter board. Ground pins 575 and 580 and signal pins 315 are coupled to ground receptacle connections 357 and signal receptacle connections 355 at mating connection points 370, 372, 345 and 347, respectively, in the connector module of the connection coupling zone. Provide electrical isolation to other signal connections.

Multiple column and column connections of the connector module may be arranged to be dense with one another. The preferred pitch is 2 mm, and it is preferable that a pair of connector modules are arranged in mirror relationship. 18 illustrates an arrangement of four example connector modules in accordance with the present invention. The connector module 583 is in a mirror relationship with respect to the connector module 585, and the connector module 593 is in a mirror relationship with respect to the connector module 595. Each signal pin 315 is shielded by a ground receptacle connection 357 at the connector module. Although four connector modules are shown in Fig. 18, other number of connector modules may be arranged.

Figure 19 shows an exemplary receptacle socket housing according to this embodiment. The receptacle socket housing 452 is preferably made of plastic and preferably covers the signal receptacle connection and the ground receptacle connection. Windows 455 and 457 are provided to receive signal pins 315 and ground pins 317 (ie, L-shaped pins 525 and 530), respectively, from the header connector. The housing 452 is similar to that shown in Fig. 13B.

The connector according to the invention can be used for intermediate planar applications. Figure 20 is a perspective view of an exemplary grounding pin and signal pin incorporated in an intermediate planar application in accordance with the present invention with parts separated. FIG. 21 is a perspective view of an exemplary grounding pin and signal pin incorporated into the midplane application of FIG. 20 with components assembled, and FIG. 22 is a side view of the two grounding pins of FIG. 20 connecting to each other.

Figure 20 shows through holes for ground pin 505, preferably consisting of two portions 510 and 520 (similar to ground pin 317) but may be formed of multiple portions, including one portion. An intermediate planar circuit board 600 with 610 is shown. Also shown is a through hole 650 for signal pin 660. The tail 515 of the ground pin connector 510 is inserted through the through hole 610 and connects to the ground pin 630 on the other side. The ground pin 630 is similar to the ground pin 317 of FIG. 15A and is preferably composed of the connecting portions 635 and 640 but may be formed in several parts including one part. The connection part 640 is the same as the connection part 520. In addition to the two exemplary pins 521, 522 and 641, 645 shown for connecting with the associated ground receptacle connection, other numbers of pins may also be located on the connections 520 and 640. The connecting portion 635 includes a protrusion 637, a ridge or bump 638, and a short tail 643. The projections 637 and bumps 638 cooperate with the projections 642 and bumps 643 to interconnect the connections 635 and 640.

21 and 22, the tail 515 of the connection 510 passing through the through hole 610 passes over the short tail 639, and the next substrate (not shown). Is electrically connected to the projection 637 to pass through ground. Ground contacts 635 and 640 are preferably located in an empty housing header without a sheath (not shown) or pin. The envelope is plugged on the back or bottom surface of the intermediate planar substrate 600, and the signal pin 660 (similar to the signal pin 315) passes through the substrate 600 and the envelope. Short tail 639 electrically shields the column of sheath.

The present invention allows a more compact form to achieve complete electrical isolation within the connection coupling zone. Moreover, the present invention maintains complete insulation in the diagonal direction.

Although ground pin (s) that engage with the combined ground receptacle connection (s) of the described embodiment are provided in an L-shape, the invention is not limited thereto. It is also possible to use other forms such as rectangles, squares and circles.

A right angle portion is provided in the socket connector of the described embodiment, but the invention is not limited thereto. For example, the present invention can be applied to a socket connector having a straight ground connection and a straight signal connection without a right angle portion.

Although described with reference to some particular embodiments, the present invention is not intended to be limited to the details set forth. Rather, various modifications may be made in the described parts without departing from the invention within the scope of the claims.

By the above-described configuration, the present invention provides a connector module that prevents crosstalk between the connection members in the connector module having a tightly dense connection member to maintain a good signal quality.

1 is a partial side view of a first embodiment of a high speed transmission connector according to the present invention with parts separated;

FIG. 2A is a cross sectional view of the connector of FIG. 1 with parts assembled; FIG.

FIG. 2B is a perspective view of the arrangement of the multiple connectors of FIG. 2A arranged in the housing with the components separated; FIG.

3 is a perspective view of an exemplary connector module in accordance with the present invention.

4 is a perspective view of an exemplary ground pin in accordance with the present invention.

5 is a perspective view of an exemplary signal pin in accordance with the present invention.

6A and 6B are perspective views of exemplary signal receptacle connections in accordance with the present invention.

7A and 7B are perspective views of exemplary ground receptacle connections in accordance with the present invention.

8A and 8B are perspective views of a pair of exemplary socket connectors with signal and ground pins coupled in accordance with the present invention.

9 is a cross-sectional view of an exemplary connector module in accordance with the present invention.

10A illustrates an arrangement of an exemplary connector module in accordance with the present invention.

10B is a schematic representation of a free body of an exemplary connector module in accordance with the present invention.

11 illustrates an exemplary socket housing in accordance with the present invention.

12 is a cross-sectional view of an exemplary connector module with a socket housing in accordance with the present invention.

Fig. 13A is a partial perspective view of another exemplary connector according to the present invention.

FIG. 13B shows an arrangement of a good ground pin and signal pin in the connector of FIG. 13A;

Figure 13C illustrates another arrangement of a good ground pin and signal pin in the connector of Figure 13A.

Figure 14 is a perspective view of the connector of Figure 13A with parts assembled.

Figure 15A is a perspective view of another exemplary grounding pin in accordance with the present invention with the components separated.

FIG. 15B is a perspective view of the pin of FIG. 15A with parts assembled; FIG.

Figure 16A is a perspective view of a pair of exemplary signal receptacle connections in mirror symmetry relationship in accordance with the present invention.

Figure 16B is a perspective view of a pair of exemplary signal receptacle connections in mirror symmetry in accordance with the present invention.

17A and 17B are perspective views of two pairs of exemplary socket connectors having signal pins and ground pins coupled in accordance with the present invention.

Figure 18 illustrates an arrangement of another exemplary connector module in accordance with the present invention.

Figure 19 illustrates another exemplary socket housing in accordance with the present invention.

Figure 20 is a perspective view of an exemplary grounding pin and signal pin coupled to an intermediate planar application in accordance with the present invention with the components in a separated state.

Figure 21 is a perspective view of an exemplary grounding pin and signal pin coupled to an intermediate planar application in accordance with the present invention with the components assembled;

Figure 22 is a side view of a portion of Figure 21;

<Explanation of symbols for the main parts of the drawings>

10: header connector

12: header housing

15: signal pin

17: ground pin

50: socket connector

55: signal receptacle connection

57: ground receptacle connection

Claims (53)

An electrical connector module comprising a header connector comprising a ground pin and a signal pin, and a socket connector comprising a ground receptacle connection and a signal receptacle connection, comprising: The ground pin is coupled to the ground receptacle connection to generate a force in the first and second directions, and the signal pin is coupled to the signal receptacle connection to generate a force in the third and fourth directions. And the forces in the third direction oppose each other and the forces in the second and fourth directions oppose each other. The connector module of claim 1, wherein the signal pin is positioned diagonally to the ground pin. 2. The ground pin of claim 1, wherein the ground pin has two adjacent sides, the ground receptacle connection has an L-shaped cross section, the signal receptacle connection has an L-shaped cross section, and the ground pin is at the two adjacent sides. And a connector module coupled to the ground receptacle connecting portion. 4. The connector module of claim 3, wherein the ground receptacle connection and the signal receptacle connection are 90 degree offset double beam connections, or the ground receptacle connection is located in an inverted direction with respect to the signal receptacle connection. The signal pin of claim 1, wherein the signal pin has a rectangular cross section and engages with the signal receptacle connection at two adjacent sides, or the first and second directions are perpendicular to each other, and the third and fourth directions are mutually opposite. Connector module, characterized in that the vertical. A header connector comprising a ground pin and a signal pin, and a socket connector comprising a ground receptacle connection and a signal receptacle connection, The ground pin is coupled to the ground receptacle connection to generate a force in the first and second directions, and the signal pin is coupled to the signal receptacle connection to generate a force in the third and fourth directions, And the forces in the third direction oppose each other, and the forces in the second and fourth directions oppose each other. The connector module of claim 6, wherein the signal pin is disposed diagonally to the ground pin. 7. The ground pin of claim 6, wherein the ground pin has two adjacent sides, the ground receptacle connection has an L-shaped cross section, the signal receptacle connection has an L-shaped cross section, and the ground pin is the two adjacent sides. And a connector module coupled to the ground receptacle connection unit. 9. The connector module of claim 8, wherein the ground receptacle connection and the signal receptacle connection are 90 degree offset double beam connections, or the ground receptacle connection is located in an inverted direction with respect to the signal receptacle connection. 7. The singular signal pin of claim 6, wherein the singer signal pin has a rectangular cross section and engages the signal receptacle connection at two adjacent sides, or wherein the first and second directions are perpendicular to each other, and the third and fourth directions are mutually opposite. Connector module, characterized in that the vertical. A connector module comprising a ground connector and a header connector including a signal pin positioned diagonally to the ground terminal, and a socket connector including a ground receptacle connection part and a signal receptacle connection part, The ground terminal combines with the connection receptacle connection portion to generate a force in a first direction, and the signal pin combines with the signal receptacle connection portion to generate a force in a second direction, and the force in the first direction is the first force. The connector module is substantially equal in magnitude to the force in two directions and is substantially opposite in direction so that the force in the first direction offsets the force in the second direction to balance the connector module. 12. The ground terminal of claim 11, wherein the ground terminal has two adjacent sides, and the ground terminal pin is coupled to the ground receptacle connection at two adjacent sides of the ground terminal pin to generate force in the first and second directions. The signal pin is coupled to the signal receptacle connection at the two adjacent sides of the signal pin to generate a force in third and fourth directions, the forces in the first and third directions opposing each other, And said forces in said second and fourth directions oppose each other. 13. The connector module of claim 12, wherein the signal pin has a rectangular cross section and engages with the signal receptacle connection at two adjacent sides. 13. The connector module of claim 12, wherein the ground receptacle has an L-shaped cross section and the signal receptacle connection portion has an L-shaped cross section. 15. The connector module of claim 14, wherein the ground receptacle connection and the signal receptacle connection are 90 degree offset double beam connections, or the ground receptacle connection is located in an inverted direction with respect to the signal receptacle connection. The connector module of claim 12, wherein the first and second directions are perpendicular to each other, and the third and fourth directions are perpendicular to each other. 12. The device of claim 11, wherein the ground terminal comprises a first connecting portion and a second connecting portion, the first connecting portion is coupled to the second connecting portion, and a plurality of ground pins are disposed on the second connecting portion. And in particular wherein said first and second connecting portions each comprise a mutually fitting structure in a cooperating relationship to couple said first connecting portion to said second connecting portion. 12. The connector module of claim 11, wherein the ground terminal includes two pins positioned in parallel spaced apart relationship. 19. The apparatus of claim 18, wherein the header connector further comprises a second signal pin positioned diagonally to the ground terminal, The socket connector further comprises a second ground receptacle connection and a second signal receptacle connection; One of the two pins of the ground terminal is coupled with the first ground receptacle connection, the other of the two pins of the ground terminal is coupled with the second ground receptacle connection, and the signal pin is the signal receptacle A second signal pin coupled with the second signal receptacle connection, in particular the two pins of the ground terminal are located in a mirror relationship, and the second ground receptacle connection is mirrored with respect to the ground receptacle connection. And the second signal receptacle connection portion is located in a mirror relationship with respect to the signal receptacle connection portion. 12. The connector module of claim 11, wherein the ground terminal has a tail, and the connector module further comprises a second ground terminal electrically connected to the tail of the ground terminal. A header connector comprising a first ground pin, a second ground pin, a first signal pin, a second signal pin, a first ground receptacle connection portion, a second ground receptacle connection portion, a first signal receptacle connection portion, A socket connector comprising a second signal receptacle connection; The first ground pin is positioned to mate with the first ground receptacle connection, the first signal pin is positioned to mate with the first signal receptacle connection, and the second ground receptacle connection is positioned to mate with the second ground pin. And the second signal pin is positioned to mate with the second signal receptacle connection, and each of the receptacle connections has an L-shaped cross section. 22. The connector module of claim 21, wherein the first and second ground and receptacle connections are in mirrored relationship. 23. The connector module of claim 22, wherein each first signal pin is positioned diagonal to the first ground pin, and each second signal pin is positioned diagonal to the second ground pin. A header connector comprising a ground pin and a signal pin, and a socket connector comprising a ground receptacle connection and a signal receptacle connection, The ground pin is coupled to the ground receptacle connection portion to generate a force in a first direction, and the signal pin is coupled to the signal receptacle connection portion to generate a force in a second direction, and the force in the first direction is the first force. And the force in the two directions is substantially the same and the direction is substantially opposite so that the force in the first direction offsets the force in the second direction to balance the connector module. The signal receptacle of claim 24 wherein the signal pin is positioned diagonal to the ground pin, in particular the force in the first direction is diagonal to the ground receptacle connection, and the force in the second direction is the signal receptacle. A connector module, characterized in that diagonal to the connection portion. A header connector comprising a generally rectangular first signal pin array and a generally rectangular second ground pin array, the first and second arrays being offset along a diagonal direction with respect to each other; A third rectangular fourth signal receptacle terminal array disposed to couple to the first signal pin array and a fourth rectangular rectangular ground receptacle terminal array disposed to couple to the second ground pin array; Receptacle connectors offset diagonally from each other, A pair of connecting elements, one connecting element generally exerting a connecting force in a transverse direction with respect to the engagement pin in a first direction and the other connecting element exerting a connecting force in a second direction perpendicular to the first direction Each signal receptacle terminal, A pair of connecting terminals, one ground receptacle connecting terminal exerting a connecting force in the transverse direction with respect to the mating pin in a direction parallel and opposite to the first direction and the other ground receptacle connecting terminal being parallel and opposing in the second direction; And each ground receptacle terminal for applying a connection force to the coupling pin in a direction. 27. The method of claim 26, wherein the first force of the connection force on the signal pin and the second force of the connection force on the ground pin are substantially the same and opposite in direction, in particular the first and second forces are perpendicular along the diagonal direction. Interconnection. A first connector having a plurality of connecting portions, A second connector module matable with the first connector and having a plurality of connections, One of the plurality of connections on the first connector is coupled in a plurality of directions that do not face one of the plurality of connections on the second connector to generate a first force, and the plurality of connections on the first connector The other one of the connecting portions is coupled in a plurality of directions not facing the other one of the plurality of connecting portions on the second connector to be substantially equal in size to the first force but opposite in direction to the first force. 2 Force generating interconnection system. 29. The interconnect system of claim 28 wherein the plurality of connections on the first and second connectors comprises an array of ground and signal connections. 30. The method of claim 29, wherein one of the signal connections on the first connector generates the first force on one of the signal connections on the second connector, and one of the ground connections on the first connector is An interconnection system for generating said second force on one of said ground connections on said second connector. 29. The interconnect system of claim 28 wherein the first connector is a receptacle mountable to a circuit board and the second connector is a header mountable to another circuit board. 29. The interconnect system of claim 28, wherein the plurality of non-facing directions is typically perpendicular to each other. 30. The interconnect system of claim 29, wherein the ground connection on the second connector each has a plurality of pins. 34. The method of claim 33, wherein the ground connection on the second connector includes the first connection and the second connection, the first connection is coupled to the second connection, and the plurality of pins are provided to the second connection. Interconnection system. 35. The interconnect system of claim 34, wherein the first and second connectors each have a plurality of projections and ridges, and the projections and ridges cooperate with each other to couple the first connection to the second connection. 34. The interconnect system of claim 33 wherein the ground terminal has a tail and the connector module further comprises a second ground terminal in electrical connection with the tail of the ground connection. 34. The interconnect system of claim 33 wherein the ground connection on the second connector has two pins. 38. The system of claim 37, wherein one of the two pins is coupled to one of the ground connections on the first connector and the other of the two pins is coupled to the other of the ground connections on the first connector. Interconnection system. The interconnect system of claim 38, wherein the two pins are disposed in a mirror relationship. 38. The interconnect system of claim 37, wherein each of the two pins has an L-shaped cross section. 39. The interconnect system of claim 38 wherein each of the signal connections of the second connector has a rectangular cross section and is coupled to a corresponding one of the signal connections of the first connector on two adjacent sides. 41. The interconnect system of claim 40 wherein the ground and signal connection on the first connector has an L-shaped cross section. 43. The interconnect system of claim 42 wherein the ground and signal contacts on the first connector are dual beam contacts that are offset 90 degrees. 43. The interconnect system of claim 42 wherein the ground connection of the first connector is disposed in an inverted direction with respect to the signal connection of the first connector. A first connector having a plurality of connections and a housing, A second connector having a plurality of connections and matable with the first connector, The connection portion has a cross-section defined by a plurality of side surfaces and includes a one-sided support mating zone extending from the housing, each of the connection portions corresponding to the first connector at non-opposite positions of at least two of the plurality of sides. Can be combined with the mating area of the connection, Each of the plurality of connections on the first connector engages with a corresponding one of the plurality of connections on the second connector to generate a force on the plurality of connections on the second connector, the force typically offsetting each other. Interconnect systems to provide a balanced interconnect system. 46. The interconnect system of claim 45 wherein the plurality of connections on the first and second connectors each comprise an array of ground and signal connections. 47. The interconnect system of claim 46 wherein the signal connection is disposed diagonally to the ground connection. 47. The apparatus of claim 46, wherein one of the signal connections on the second connector has a first force, and one of the ground connections on the second connector is the same size but opposite direction to the first force. An interconnection system having a second force. 46. The interconnect system of claim 45, wherein the first connector is a receptacle mountable on a circuit board and the second connector is a header mountable on another circuit board. 50. The apparatus of claim 49, wherein at least one of the plurality of connections extends away from the header at a first distance, and at least another one of the plurality of connections is away from the header at a second distance shorter than the first distance. Extended interconnection system. 51. The apparatus of claim 50, further comprising a circuit board having first and second through holes, wherein one of the connections of the header passes through the first through hole and corresponds to the receptacle located on the other side of the circuit board. And an electrical connection with a connecting portion, the other of said connecting portions of said header passing through a second through hole. Electrical connectors suitable for joining mating electrical elements to form a system, With insulating housing, A plurality of multi-beam connections, wherein the connections are suitable for mating with corresponding connections on the mating element at non-opposite positions, each beam of the connecting portion having a structure for engaging with the other side of the corresponding connection on the mating element. And each of the connections generates a force, the force being typically offset from each other to provide a balanced system. 53. The electrical connector of claim 52 wherein the multibeam contact is a dual beam contact.