CN215896885U - High-speed backplane connector plug and differential electric connection part and shielding module thereof - Google Patents

Abstract

The application provides a high-speed back panel connector plug and difference electricity connection portion, shielding module thereof includes: the shielding group middle part of the first shielding piece and the second shielding piece is provided with a wing part higher than the surface of the middle part to isolate crosstalk between adjacent signal groups, the shielding connecting piece electrically connected with the first shielding piece and the second shielding piece is also arranged, the shielding connecting piece is positioned between the second side surface of the first shielding piece and the second side surface of the second shielding piece, one side of the shielding connecting piece is electrically interconnected with the second side surfaces of all shielding groups in the first shielding piece, the other side of the shielding connecting piece is electrically interconnected with the second side surfaces of all shielding groups in the second shielding piece, and the two sides of the shielding connecting piece are communicated. The shielding module realizes common ground interconnection of the contact area signal loops of the plug and the socket, can effectively inhibit the resonance problem of crosstalk in high-speed connector transmission, and ensures the signal quality at the rate of 56Gbps and above.

Description

High-speed backplane connector plug and differential electric connection part and shielding module thereof

Technical Field

The application relates to the technical field of communication equipment, in particular to a high-speed backplane connector plug and a differential electric connection part and a shielding module thereof.

Background

The connector is used for erecting a bridge for communication between circuit substrates at a blocked position or among isolated and non-communicated circuits in the circuit, so that current flows and the circuit realizes a preset function. Due to the demand for increased bandwidth of communication terminals such as switches, routers, modems (modems), and user access terminal devices, there is a higher demand for high-rate transmission and signal integrity (signal integrity) of connector signals. In a high-speed Docking Connector (Docking Connector), a differential signal is widely used with good anti-interference performance. A conventional high-speed backplane connector generally includes signal sets arranged on an insulating base at intervals, a shielding set is arranged between adjacent signal sets, and a plurality of shielding sets form a shielding plate. Each signal group generally includes differential signal terminals for transmitting differential signals; the shielding groups are used for shielding differential signals transmitted by two adjacent signal groups, and the shielding groups and the signal groups are arranged in a staggered mode, so that the shielding effect among transmission signals can be achieved, and meanwhile, a return path is provided for the transmission signals.

With the continuous increase of signal transmission rate, higher requirements are put forward on the integrity of transmission signals, and high-speed electrical performance indexes such as crosstalk, loss and reflection need to be considered. Therefore, the specific design of the shield sets, the shield blades, and the signal return path is important.

To solve the problem of crosstalk. In the prior art, a plurality of rib-shaped protrusions (bulges) are formed on a shielding substrate by stamping along the extension direction of a shielding group, as shown in fig. 1, a signal group is installed in a concave shielding cavity defined by adjacent protrusions, so that signal interference of adjacent signal groups is isolated, and meanwhile, as each shielding group is located on the same shielding substrate and is communicated with each other, a shielding sheet composed of the shielding groups is enabled to have good signal backflow. However, the height of the protrusions between different shield groups is easily inconsistent due to the whole stamping process, and cracks and the problem that the shield substrate near the protrusions is stretched are easily caused, so that uncertainty of impedance on a reflow path is generated, the shielding performance fluctuates, and the transmission performance is affected. In addition, the overall surface of the shielding plate is a non-planar surface with a wavy shape, and the shielding plate is not beneficial to reducing loop self-inductance and managing resonance as a signal return path.

In addition, because the contact point of the plug signal group and the socket signal group is not located at the tail end of the signal group, the contact point of the corresponding plug shielding group and the socket shielding device is also not located at the tail end of the plug shielding group, a part from the tail end of the shielding group to the contact point is a stub, the stub of the shielding group is reduced, the backflow path is shortened, the contact point of the shielding group and the plug is usually added on the socket, as shown in fig. 2, the socket shielding sheet 19 is added, and meanwhile, because the shielding sheet 19 is of an integrated structure, the contacts of the shielding group at the stub are interconnected through the shielding sheet 19. Specifically, the receptacle ground contact 12 protrudes from the insertion region to be inserted into and contacted with the mating receptacle ground contact 22, the receptacle shield 19 is disposed opposite to the receptacle ground contact 12, the receptacle shield 19 overhangs the insertion region, and a convex hull 191 is punched at a position corresponding to the receptacle ground contact 22, the convex hull 191 is inserted into and contacted with the receptacle ground contact 22, that is, the receptacle ground contact 22 is sandwiched between the receptacle shield 19 and the receptacle ground contact 12. According to the connector structure, the socket shielding sheet provides backflow and shielding effects in the socket, the backflow path is shortened in the insertion area through the contact of the convex hulls and the plug grounding contact pieces 12, and the problems of insertion loss and crosstalk resonance of the high-speed backplane connector are solved. However, when the socket shielding plate is matched with the grounding contact element in the socket connector, the complete shielding reference above the signal terminal is easily broken, the backflow path is influenced, and a single convex hull cannot realize the contact of a plurality of contacts at the convex hull, so that the grounding contact element of the plug generates a stub effect. Moreover, the complexity of the shielding structure is increased, and the requirement on assembly tolerance is stricter.

Based on this, for the design of the shielding plate, in the prior art, the problem that the shielding structure is more complicated and the material consumption is more and the like because of the inconsistency of the processing technology, the weak capability of the shielding plate for controlling the resonance due to the fluctuation, the poor interconnection effect of the shielding group contact at the mutual matching position of the plug and the socket, or the realization of the common ground interconnection is required.

SUMMERY OF THE UTILITY MODEL

Based on the above, the utility model provides a high-speed backplane connector plug, a differential electrical connection part thereof and a shielding module

At least the problems mentioned in the prior art can be solved.

In a first aspect, a shielding module for a high-speed backplane connector plug is provided, including: a first shield plate and a second shield plate; the first shielding sheet and the second shielding sheet respectively comprise a plurality of shielding groups;

each shielding group comprises a contact part electrically connected with the socket, a mounting part formed by extending the contact part along a preset direction and electrically connected with the circuit substrate, and a middle part connecting the contact part and the mounting part; at least one wing part is arranged in the middle part along the preset direction; the wing part is formed in the middle part, one end of the wing part is fixed on the middle part, and the other end of the wing part is separated from the surface of the middle part and is bent to a preset height relative to the surface of the middle part; the concave space defined by the surfaces of the opposite wing parts and the middle parts on every two adjacent shielding groups is used for placing the plug signal group;

the middle parts of all the shielding groups contained in the first shielding sheet are positioned on the same shielding substrate;

the middle parts of all the shielding groups contained in the second shielding sheet are positioned on the same shielding substrate;

the contact portion includes a first side in electrical contact with the receptacle shield set, and a second side opposite the first side; the second side surface of the contact part in the first shielding sheet is opposite to the second side surface of the contact part in the second shielding sheet;

the shielding module further comprises a shielding connecting piece, the shielding connecting piece is located between the second side face of the contact part in the first shielding piece and the second side face of the contact part in the second shielding piece, one side of the shielding connecting piece is electrically interconnected with the second side faces of all the contact parts in the first shielding piece, the other side of the shielding connecting piece is electrically interconnected with the second side faces of all the contact parts in the second shielding piece, and two sides of the shielding connecting piece are communicated.

In the scheme, on one hand, the wing parts of the adjacent shielding groups are higher than the surface of the middle part, and the recess space which is jointly limited in the plane of the wing parts and the surface of the middle part is used for installing the socket signal group, so that a three-side shielding structure is formed, and the adjacent signal group interference is shielded and isolated. The shielding groups are arranged between the adjacent signal groups and used for respectively carrying out electromagnetic shielding isolation on each signal group so as to reduce mutual crosstalk of differential signals between the adjacent signal groups, thereby being beneficial to improving the stability, reliability and anti-interference capability of the electric connector during data transmission; also, the area where the set of plug signals is plugged into the set of jack signals constitutes an area of significant impedance discontinuity, requiring more return current paths for the return current to switch on different paths. In the application, the middle parts of different shielding groups are positioned on the same shielding substrate, the parts of different middle parts, which do not form the wing parts, are communicated with each other, the return current is switched on the shielding substrate and returns to the mounting part from the shortest path, and the resonance problem of crosstalk in the transmission of the high-speed backplane connector can be effectively suppressed.

On the other hand, in the transmission line, that is, the plug signal group and the jack signal group described in the present application, when a signal voltage is applied to the plug signal group, a potential difference occurs between the signal group path and the return current path, and even if the end of the signal group is opened, the return voltage still exists. In order to meet the plugging requirement, the contact positions of the plug signal group and the socket signal group are not located at the respective ends, so that the part of the signal group from the contact point to the end does not belong to the signal flow passage, but the part still generates return current. This application increases shielding connection piece, its second side electrical connection with the contact site of first shielding piece and second shielding piece respectively to shielding group stub department passes through shielding connection piece electrical interconnection, has realized the interconnection of sharing the earth of contact area signal return circuit, has improved the backward flow effect, and shielding connection piece need not occupy more installation space, sets up the signal group to the high density and is favorable with shielding group.

Optionally, the connection mode of the shield connecting sheet and each second side surface may be any one of metal elastic interconnection, conductive adhesive or plastic electroplating.

Further, the projection part of the first shielding sheet contact part on the surface where the second shielding sheet is located between the contact parts of the second shielding sheets.

Optionally, the shielding connecting piece includes elastic pieces whose two sides are in electrical contact with the second side surface, and a base portion communicating the elastic pieces at the two sides, and the elastic pieces at the two sides respectively press against the second side surface of the first shielding piece and the second side surface of the second shielding piece.

Optionally, the direction of the force applied by the first shielding plate to the shielding connecting sheet is opposite to the direction of the force applied by the second shielding plate to the shielding connecting sheet.

Furthermore, in the direction of inserting the plug into the socket, the interconnection point of the shielding connecting sheet and the second side surface is positioned below the contact point of the first side surface of the contact part and the socket shielding group.

Optionally, the length of the wing part on different shielding groups is different, and the maximum length of the wing part is less than 4 mm.

In a second aspect, a differential electrical connection portion is provided, which includes the shielding module of the first aspect and possible embodiments of the first aspect, and further includes a signal group that is spatially matched with the recess in the shielding module, and an insulating member that is matched with the signal group, where the signal group includes a contact portion and a mounting portion that is formed by extending the contact portion along the predetermined direction; the signal group is insulated from the shield substrate.

Further, the signal group comprises two differential signal pins, and the transmitted signals are opposite in polarity.

In a third aspect, a high-speed backplane connector plug is provided, which includes the differential electrical connection portion of the second aspect and the possible embodiments of the second aspect, and a plug housing for accommodating the differential electrical connection portion, wherein the shielding group and/or signal group contact portion in the differential electrical connection portion is supported and limited by the plug housing.

Drawings

FIG. 1 is a schematic view of a prior art bump;

FIG. 2 is a schematic diagram of a return contact in a prior art socket area;

FIG. 3 is a schematic view of a receptacle and a plug being plugged together to form a connector according to an embodiment of the present invention;

FIG. 4 is a schematic diagram of a receptacle and a plug mated together to form a connector according to an embodiment of the present invention;

FIG. 5 is a cross-sectional view of a mating receptacle and plug in accordance with one embodiment of the present invention;

FIG. 6 is an enlarged view of a portion of FIG. 5 taken in cross-section D;

fig. 7 is a schematic view of a plug that does not include shield tabs according to an embodiment of the present invention;

FIG. 8 is a schematic view of a plug in a direction opposite to the plugging direction according to an embodiment of the present invention;

FIG. 9 is a schematic view of a shielding module according to the present invention;

FIG. 10 is a schematic view of the embodiment of a shielding module of FIG. 9 in a direction opposite to the plugging direction;

FIG. 11 is a schematic view of a plurality of embodiments of a shielding module of FIG. 9;

FIG. 12 is a schematic view of another surface of the embodiment of a shielding module of FIG. 9;

FIG. 13 is a schematic view of a first shield plate and a shield assembly according to an embodiment;

FIG. 14 is another schematic view of the first shield segment embodiment of FIG. 13;

FIG. 15 is another schematic view of the first shield segment embodiment of FIG. 13;

FIG. 16 is a schematic view of a second shield plate and a shield assembly according to an embodiment;

FIG. 17 is another view of the second shield segment of the embodiment of FIG. 16;

FIG. 18 is another view of the second shield segment of the embodiment of FIG. 16;

FIG. 19 is an assembled view of an electrical connection A including a first shield sheet according to an embodiment of the present invention;

FIG. 20 is another view of electrical connection A of FIG. 19;

FIG. 21 is a schematic diagram of a signal group included in the electrical connection portion A of FIG. 19;

FIG. 22 is an assembled view of the signal set contained in the electrical connection portion A of FIG. 19;

FIG. 23 is an assembled view of an electrical connection B including a second shield sheet according to an embodiment of the present invention;

FIG. 24 is another view of electrical connection B of the embodiment of FIG. 22;

FIG. 25 is a schematic diagram of a signal group included in the electrical connection portion B in the embodiment of FIG. 22;

FIG. 26 is a schematic diagram of the assembly of the signal set contained in the electrical connection B of the embodiment of FIG. 22;

FIG. 27 is a schematic recess space view;

FIG. 28 is a schematic view of a shield connecting tab according to an embodiment of the present invention;

fig. 29 is another view of a shield connecting tab in accordance with an embodiment of the present invention;

figure 30 is a schematic view of a plug without shield tabs according to an embodiment of the present invention;

FIG. 31 is a schematic view of a plug assembly according to an embodiment of the present invention.

FIG. 32 is a graph comparing near end crosstalk for embodiments of the present invention having wings less than 4 mm.

Description of the main element symbols:

Detailed Description

In order to make the objects, principles, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration and are not intended to limit the utility model, as described in this summary of the utility model.

It should be particularly noted that, according to the connection or position relationship that can be determined according to the text or technical content of the specification, a part of the omitted or not-shown position change diagram is omitted for the simplicity of drawing, the omitted or not-shown position change diagram is not explicitly described in the specification, and cannot be considered to be omitted, and in the interest of brevity of description, the detailed description is not repeated one by one, and the description is unified herein.

In the following, briefly described as a backplane connector according to the present application, the backplane connector includes a plug and a socket (or "male" and "female" respectively), signals flow from the plug to the socket, one side of the plug is connected to the circuit board, and the other side of the plug is mated with the socket. Specifically, because the signal pins inside the plug are matched with/contacted with the corresponding signal pins in the socket, and due to the improvement of the transmission rate, two signal pins usually form a pair of differential signal pins, and signal interference between adjacent differential signal pins needs to be shielded. Namely, it is necessary to shield both the signal interference between the plug-end differential signal pins and the signal interference between the receptacle-end differential signal pins.

Therefore, it can be understood that the socket shielding plate proposed in the present application is used for shielding interference between the plug end signal groups, and is particularly suitable for connectors using differential signal pins to transmit signals. It should be noted that the following embodiments of the present application all use signal groups as differential signal pins for example, but do not exclude the shielding module of the present application from being used for shielding non-differential signals.

Accordingly, referring to fig. 9 to fig. 11, a shielding module 5 according to an embodiment of the present application is schematically illustrated, and includes: a first shield sheet 51 and a second shield sheet 52; the first shielding sheet 51 and the second shielding sheet 52 respectively comprise a plurality of shielding groups 501; each shield set 501 includes a contact portion electrically connected to the socket shield set 501, a mounting portion electrically connected to the circuit board and formed by extending the contact portion along a predetermined direction, and an intermediate portion connecting the contact portion and the mounting portion, and along the predetermined direction, the intermediate portion is provided with at least one wing portion 5016, and a recess space defined by the wing portions 5016 and the intermediate portion facing each other on every two adjacent shield sets 501 is used for placing the plug signal set 601. The wing part 5016 is formed in the middle part, one end of which is fixed to the middle part, and the other end of which is bent to a predetermined height from the surface of the middle part; all the shield group intermediate portions 5013 included in the first shield plate 51 are located on the same shield substrate 502;

all the shield group intermediate portions 5013 included in the second shield plate 52 are located on the same shield substrate 502. It should be understood that the shielding substrate 502 of the first shielding plate 51 and the shielding substrate 502 of the second shielding plate 52 do not refer to the same shielding substrate 502.

The contact portion includes a first side in electrical contact with the receptacle shield set 501, and a second side opposite the first side; the second side of the first shield plate 51 faces the second side of the second shield plate 52. It is understood that the position of the first side surface of the first shield plate 51 with respect to the shield group contact portion 5011 constituting the first shield plate 51 is different from the position of the first side surface of the second shield plate 52 with respect to the shield group contact portion 5011 constituting the second shield plate 52, the former being located on the right side of the contact portion shown in the drawing and the latter being located on the left side of the contact portion shown in the drawing.

It is to be understood that the contact portion belongs to a part of the shielding set 501, the shielding set 501 constitutes the first and second shielding plates, and further, for the convenience of description, the following descriptions of "the first and second side surfaces of the first shielding plate 51", "the first and second side surfaces of the second shielding plate 52", etc. are to be understood as corresponding to the first and second side surfaces of the contact portion.

It should be noted that the shield group 501 of the first shield plate 51 and the shield group 501 of the second shield plate 52 have substantially the same structure, and the difference is that the position where the plug signal group 601 is arranged is different. Specifically, the plug signal group 601 fitted to the first shield plate 51 is disposed on the same side as the first side surface of the contact portion, and the plug signal group 601 fitted to the second shield plate 52 is disposed on the same side as the second side surface of the contact portion. Therefore, in the present application, the shield group 501 of the first shield plate 51 is not distinguished from the shield group 501 of the second shield plate 52, and both the shield group 501 of the first shield plate 51 and the shield group 501 of the second shield plate 52 satisfy the above-described limitation condition on the structure of the shield group 501 itself.

It will be appreciated that the predetermined direction in which the shield set contact portions 5011 extend is determined by the angle of the shield set contact portions 5011 relative to the circuit substrate. Alternatively, in one embodiment of the connector shown in fig. 3 to 5, the plane of the contact end is parallel to the plane of the circuit substrate to which the plug is connected. Thus, in this embodiment, the predetermined direction means that the shield set 501 extends vertically downward to form a shield set mounting portion 5012, and the shield set 501 is substantially I-shaped. In addition, the shape of the signal set 601 to be mounted and assembled is also considered, that is, the extending direction of the concave space needs to be approximately consistent with the direction of the signal set 601 to be mounted and the direction of the signal set 601 needs to avoid straight corners, through holes and the like, and correspondingly, the shielding set contact part 5011 is optionally an arc line in the predetermined direction for extending to form the mounting part.

Specifically, the shielding modules 5 in the header and the socket need to be interconnected, and referring to fig. 3 to 8, in this embodiment, the connector 1 includes the header 2 and the socket 3, and each shielding group contact portion 5011 of the header 2 is in electrical contact with the socket to form an interfitting region. It will be appreciated that the receptacle 3 is also provided internally with a corresponding receptacle shield 80, so that more particularly, as shown in the enlarged detail view of fig. 6, the plug shield set contacts 5011 of the present application electrically connect the shields in the receptacle. Optionally, the shielding of the receptacle may be shaped substantially the same as the shielding group contacts 5011 in the mating area, and the plug may form the shielding contacts T when plugged into the receptacle.

In this embodiment, referring to fig. 9 and 13 to 15, or referring to fig. 9 and 16 to 18, since the wings 5016 of the adjacent shielding sets 501 are higher than the surface of the middle portion, the recessed space defined by the adjacent shielding sets 501 and the surface of the middle portion is used for mounting the jack signal sets 601, so as to form a three-sided shielding structure, and shield the adjacent signal sets 601 from crosstalk when transmitting signals at high speed.

It should be noted that the recess space referred to in this application is a three-sided shield structure consisting of two adjacent wing portions 5016 as side surfaces and a middle portion as a solid bottom surface, and then the solid bottom surface of the middle portion serves as a part of the return path of the return current.

Here, it is explained that the "intermediate portion" of the different shield groups 501 is located on the same shield substrate 502 for one shield piece, and the shield substrate 502 is made of the same material as the shield group contact portion 5011 and the shield group attachment portion 5012. As an example of the shield sheet structure, a plurality of shield group contact portions 5011 are arranged side by side and electrically connected to one vertical surface of the shield substrate 502, and all the corresponding shield group mounting portions 5012 are electrically connected to the other vertical surface of the shield substrate 502. In the embodiment of the present application, it is preferable that the shield group contact part 5011, the shield substrate 502, and the shield group mounting part 5012 are integrated. For the shield substrate 502 without the wing portion 5016, the return current of the shield group mounting portion 5012 can flow on an arbitrary path on the planar shield substrate 502 and return to the shield group contact portion 5011, that is, the solid bottom surface of the aforementioned intermediate portion belongs to a part of the shield substrate 502.

Therefore, the intermediate portion in the present application is described only for the convenience of dividing the shield group 501, and it should not be understood that the shield group intermediate portions 5013 are separated and independent from each other, and are understood to correspond to the regions divided by the shield group contact portions 5011 and the mounting portions on the shield substrate 502. Of course, for the following lead-in tab 5016 embodiments, the intermediate portion is understood to correspond to the area on the shield substrate 502 divided by the shield group contact portion 5011 and the mounting portion, the tab 5016.

In this case, the recessed space referred to in the present application can be understood as a three-sided shield structure in which the wing portions 5016 of two adjacent shield groups 501 face each other as side surfaces and the shield substrate 502 as a solid bottom surface, and the solid bottom surface of the shield substrate 502 serves as a part of a return path for return current.

Thus, the spacing of the shield sets 501 may be understood as the spacing between the shield set contact portions 5011, or between the shield set mounting portions 5012, or between the wings 5016 of the adjacent shield set intermediate portions 5013, which spacing accommodates the jack signal sets 601 matching the shield sets 501, and the spacing of the shield sets 501 making up the same shield plate is generally the same, and the present application does not limit the specific size of the spacing that is sufficient to accommodate the signal sets 601.

Referring specifically to fig. 14 or 17, the fins 5016 face the side of the shielding set 501 where the signal group 601 is disposed, and a plurality of fins 5016 bent to a predetermined height along the predetermined direction isolate the adjacent signal groups 601, shielding the adjacent signal groups 601 from crosstalk along the plane a of the shielding substrate 502.

It should be understood that the shielding set 501 is disposed between adjacent signal sets 601 for shielding and isolating each signal set 601, so as to reduce mutual crosstalk between signals of the adjacent signal sets 601, thereby helping to improve stability, reliability and anti-interference capability of the electrical connector during data transmission.

For the design of the path of the return current, in the different shield group intermediate portions 5013, the portions where the wings 5016 are not formed communicate with each other, that is, the shield groups 501 communicate with each other. It is to be understood that the "portion where the wings 5016 are not formed" is the solid shield substrate 502. The signal current direction is opposite to the return current direction, the jack signal group 601 is electrically connected with the plug signal group 601 to transmit signals, and the return current can be switched through a different path formed on a portion of the middle portion where the wing 5016 is not formed, near the impedance discontinuity region on the signal current path, thereby alleviating the influence of the abrupt change in impedance. In addition, the interconnection between the shielding groups 501 changes the return current loop inductance, reducing the inductive discontinuities experienced by the signal, thereby improving signal transmission, reducing insertion loss ripple, and improving resonance.

As for the formation of the wing portions 5016, it is understood that the cut grooves 5015 are formed in the middle portion, and the wing portions 5016 are formed by lifting or bending the cut grooves 5015, and one end thereof is fixed to the middle portion or the shield substrate 502, and the other end thereof is movable relative to the middle portion. The shape of the wing 5016 is not particularly limited, and the shape of the cut slot 5015 is determined by the shape of the predetermined wing 5016, for example, the wing 5016 is an inverted trapezoid with a fixed upper bottom and a movable lower bottom, and the corresponding cut slot 5015 is a trapezoid with an upper bottom, or the wing 5016 is a rectangle with one side fixed to the shielding substrate 502 and the opposite side movable with respect to the shielding substrate 502, and the corresponding cut slot 5015 is a rectangle with the other side of the fixed end. Optionally, the heights H1 of the wings 5016 between the different shielding groups 501 are the same with respect to the plane of the shielding substrate 502, which facilitates the batch processing and the uniformity of the shielding effect, and meanwhile, the connection line between the fixed end and the movable end is generally perpendicular to the plane a of the shielding substrate 502. Preferably, the height H1 is 0.4mm in order to reduce the thickness of the shield plate to increase the density of the arrangement and to satisfy the isolation between adjacent signal groups 601.

From the perspective of the processing technology, by using blanking, wire cutting along the predetermined direction, or because the extending directions of the shielding sets 501 are consistent, a mask is made to etch the cutting grooves 5015 with corresponding shapes, and then the wing portions 5016 with one end fixed and the other end opposite to the surface of the shielding substrate 502 to a predetermined height are formed by bending, and the wing portions and the middle portion define the concave mounting space of the signal set 601 together, so as to avoid the crosstalk between the adjacent signal sets 601. Further, due to the design and the processing technology of the wing portion 5016, compared with the existing stamping technology, the processing technology is higher in accuracy, the surface processing can well avoid impedance discontinuity caused by local stretching of the surface of the shielding substrate 502, and the yield is high; the fins 5016 between the plurality of shield sets 501 have good consistency, specifically, the fins 5016 between the plurality of shield sets 501 have good height consistency, and the length of the fins 5016 can be processed with more accurate precision. The middle parts 5013 of different shielding groups approaching the signal group 601 and the same shielding group 501 are positioned on the same plane at intervals, so that the return paths of return currents are positioned on the same plane, the return currents can be switched on different shielding conductor paths, the loop self-inductance is favorably reduced, the inductive mutation suffered by the signals is reduced, the return currents of different shielding group installation parts 5012 can return to the shielding group contact part 5011 along the nearest path, the impedance of each area on the shielding substrate 502 is more controlled, the insertion loss fluctuation and the resonance are favorably reduced, and the signal transmission is improved.

It should be noted that the shielding plate proposed in the present application can improve the discontinuous impedance region on the shielding substrate 502 by bending the wing portions 5016 to a predetermined height to achieve electromagnetic isolation between adjacent signal groups 601 along the plane a of the shielding substrate 502, and since the wing portions 5016 are formed on the shielding substrate 502, the portions where the wing portions 5016 are not formed form a plurality of paths of return current in the same plane. And since the wing 5016 is formed on the shield substrate 502 through which the return current passes, it is possible to form more paths of the return current on the shield substrate 502 by setting the position and size of the wing 5016 more freely. It is understood that the functions of the present application of avoiding crosstalk between adjacent signal groups 601 and managing resonance are performed by the same first shield plate 51 or second shield plate 52.

Further, the length of the wing 5016 in the predetermined direction does not exceed 4mm at maximum, which can satisfy both good crosstalk prevention and better management of resonance.

In some applications, the wings 5016 are used for fixing the first and second shielding plates to the signal group 601 during assembly, and optionally, the wings 5016 are provided with notches 5017 to make the first and second shielding plates more reliable after assembly with the signal group 601; meanwhile, in order to avoid the gap 5017 from affecting isolation of crosstalk between the signal groups 601, the connection line of the gap 5017 on the same first shielding plate 51 or the same second shielding plate 52 is undulated along the arrangement direction of the shielding groups 501.

With continued reference to fig. 9 to 12, the shielding module 5 further includes a shielding connecting sheet 53, the shielding connecting sheet 53 is located between the second side surface of the first shielding sheet 51 and the second side surface of the second shielding sheet 52, one side of the connecting sheet is electrically interconnected with the second side surfaces of all the shielding groups 501 in the first shielding sheet 51, the other side of the connecting sheet is electrically interconnected with the second side surfaces of all the shielding groups 501 in the second shielding sheet 52, and the two sides of the shielding connecting sheet 53 are communicated.

It should be noted that, in connection with fig. 5, in the present application, the term "electrically interconnected" means that each second side is electrically connected to the shield connecting piece 53, and through the shield connecting piece 53, the return current between the corresponding second sides of each side of the shield connecting piece 53 is communicated, and the second sides between one side and the other side of the shield connecting piece 53 are also communicated.

Referring to fig. 27 and 28, the present application does not limit the specific electrical connection manner between the shielding connecting piece 53 and the second side surface, and only needs to satisfy that after the shielding connecting piece 53 is point-connected to the second side surface, the whole shielding connecting piece 53 also serves as each part of the return current path. Alternatively, the shield connecting pieces 53 may be interconnected by metal elasticity, that is, the shield connecting pieces 53 are entirely made of metal, in another embodiment, the shield connecting pieces 53 may be made of non-metal substrate, the interconnection is realized by coating conductive adhesive or plastic electroplating of the shield connecting pieces 53,

it should be understood that plugging a plug into a socket is a dynamic process, and specifically, the end of the signal group 601 contacts the end of the socket signal group 601 along the plugging direction, and continues downward along the plugging direction, the position of the contact point on the plug signal group 601 with the socket signal group 601 changes, and after reaching a predetermined plugging depth, the contact point of the plug signal group 601 with the socket signal group 601 is located at the end of the plug signal group 601, and the connection line between the contact point and the end is in an open circuit state. According to the transmission line theory, the transmitted signal still has a return signal even in the aforementioned open path, and correspondingly, on the shielding module 5, referring to fig. 5 and 6, the plug shielding group contact portion 5011 and the socket shielding device 80 form a shielding contact T, and for the plug, the part of the stub 5014 from the shielding contact T to the end of the shielding group contact portion 5011 has a return current, the signal encounters a large impedance jump when passing through the stub 5014, and under the influence of the reflection superposition, the return signal needs a more free return path to improve the return effect of the return signal. The common form of adding contacts, as mentioned in the background section of this application, interconnects a row of contacts by adding a shield at the receptacle end, but the added shield is parallel to the original shield, which creates a high requirement for assembly of the contacts to the header shield assembly 501, and increases the thickness of the shield module 5 and the force of insertion and removal. For example, the contact positions of the plug shielding sets 501 and the receptacle shielding devices 80 are changed, that is, the plug shielding sets 501 are inserted into the receptacle shielding devices 80, and it is necessary to keep the contacts of a plurality of receptacle shielding devices 80 to press the plug shielding sets 501 in real time, which is not favorable for the arrangement of the high-density shielding sets 501, and affects the space utilization rate.

In the present application, the shield connection piece 53 is located between the first shield piece 51 and the second shield piece 52, and the size of the shield connection piece 53 depends on a predetermined interval between the first shield piece 51 and the second shield piece 52. Since, for differential signals, a certain interval itself needs to be maintained between the signal group 601 to which the first shield plate 51 is mated and the signal group 601 to which the second shield plate 52 is mated, the shield plates are mounted at the interval, and thus the shield connecting piece 53 of the present application does not need an excessive mounting space.

Preferably, the first shielding plate 51 is disposed in parallel with the second shielding plate 52 to fully utilize the installation space and satisfy the condition of high-density signal pin arrangement. Therefore, for some arrangements using the first shielding plate 51 and the second shielding plate 52 at an acute angle, the inferior technology and solution should be considered, and should not be considered as the protection scope of the present application. Accordingly, the shield connecting piece 53 is substantially parallel to the first and second shield pieces 51 and 52 because it is located between the first and second shield pieces 51 and 52 in the shape of the shield connecting piece 53.

As for the specific structure of the shield connecting piece 53, it is preferable that the shield connecting piece 53 includes an arcuate spring 531 of which both sides are in electrical contact with the second side surface, and a base 532 communicating the spring 531 of both sides, and the plane of the base 532 is parallel to the first shield piece 51 and the second shield piece 52.

The shape of the base 532 is not particularly limited in the present application, and alternatively, the base 532 may be S-shaped and meander along the space defined by the first shield plate 51 and the second shield plate 52. The base 532 is flat in view of simplifying the overall process of the shield connecting piece 53. The arched elastic pieces 531 on the two sides respectively press against the second side surface of the first shielding piece 51 and the second side surface of the second shielding piece 52, and the whole shielding connecting piece 53 is of an inverted trapezoidal structure. In combination with the above, the material selection of the shielding connecting piece 53 is not limited to the metal base material, and the material with the changed elastic shape may be selected, so that the shielding connecting piece 53 is held between the second side surfaces of the first and second shielding pieces.

With reference to fig. 8 to 12, and fig. 30 and 31, it can be understood that, during assembly, the first and second shield plates and the signal set 601 are assembled and then mounted on the plug housing 70, and the plug housing 70 supports and limits the shield set contact portion 5011 and the signal set contact portion 6011, thereby preventing the shield set contact portion 5011 from being deformed during assembly of the shield connecting plate 53. The shielding connecting piece 53 is pressed between the first shielding piece 51 and the second shielding piece 52, and both sides of the shielding connecting piece 53 are respectively subjected to the pressing force F1 of the second side surface of the contact part in the first shielding piece 51 and the pressing forces F2, F1 and F2 in the second shielding piece 52 in opposite directions, so that the shielding connecting piece 53 can be well clamped between the first shielding piece 51 and the second shielding piece 52. The adoption of one shielding connecting sheet 53 solves the problems of common ground interconnection and contact increase of the two rows of shielding groups 501, and reduces the assembly procedures and materials. Preferably, referring to fig. 6 and 9, in the direction of the plug-in socket, the interconnection point Q of the shield connecting piece 53 and the second side is located below the shield contact T of the contact portion first side and the socket shield set 501.

Therefore, in the shielding module 5 composed of the first shielding plate 51, the second shielding plate 52 and the shielding connecting plate 53, on one hand, the design of the wing portions 5016 of the first shielding plate 51 and the second shielding plate 52 can shield and isolate the interference of the adjacent signal groups 601, thereby being beneficial to improving the stability, reliability and anti-interference capability of the electric connector during data transmission; also, the area where the set of plug signals 601 is plugged into the set of jack signals 601 constitutes an area of significant impedance discontinuity, requiring more return current paths for the return current to switch on different paths. In the present application, the intermediate portions 5013 of different shield groups are located on the same shield board 502, and the portions of the different intermediate portions not having the wings 5016 communicate with each other, so that the return current is switched on the shield board 502 and returns to the mounting portion from the shortest path, thereby effectively suppressing the resonance problem of crosstalk in high-speed backplane connector transmission.

On the other hand, a shield connecting piece 53 interconnecting the first shield piece 51 and the second shield piece 52 is provided. Thus, return currents at stubs 5014 of the shielding group 501 are electrically interconnected through the shielding connecting pieces 53, common ground interconnection of signal circuits in contact areas of the plug and the socket is achieved, the backflow effect is improved, the shielding connecting pieces 53 do not need to occupy more installation space, and the high-density arrangement of the signal group 601 and the shielding group 501 is beneficial. In addition, except that the first shielding sheet 51 and the second shielding sheet 52 are connected in common, the backflow effect is improved, the shielding module 5 formed by assembling the shielding connecting sheet 53 and the first and second shielding sheets is high in structural reliability, specifically, two sides of the shielding connecting sheet 53 respectively press against the first shielding sheet 51 and the second shielding sheet 52, and due to the fact that a plurality of second side surfaces exist, a plurality of stress points exist on the shielding connecting sheet 53, the first shielding sheet 51 and the second shielding sheet 52, the shielding connecting sheet 53 is enabled to be subjected to sufficient holding force, the plug and the socket are not prone to falling off in the process of multiple plugging and pulling-out, the reliability of signal transmission and the shielding effect is improved, and the plug is guaranteed to be used for transmitting signals with the speed of more than 56 Gbps.

The following describes the mounting of the first and second shield plates in cooperation with the signal group 601. Referring to fig. 16 or fig. 18, the assembly of the shielding plate shown in fig. 8 and the shielding plate set of socket signals 601 shown in fig. 12 is illustrated. As shown in the figure, the signal group 601 is first combined with the insulating member 60, and is usually integrally molded in a plastic package of the signal group 601; of course, the plastic insulator 60 having the insertion holes for matching with the signal sets 601 may be formed first, the signal sets 601 are attached to the insertion holes to form the entire row of signal sets 601, and then the entire row of signal sets 601 is detachably mounted to the shield plate. Alternatively, the means for detachable attachment herein include, but are not limited to, snap-fit, plug-in, weld, and rivet.

Specifically, taking the signal group 601 including two differential signal pins as an example, the wing portions 5016 of the differential signal pins in a pair of differential signal pins corresponding to the adjacent shield group 501 are fitted into the recessed space of the three-sided shield defined by the middle portion, as can be seen in fig. 27, the differential signal pins including contact portions and mounting portions formed by extending the contact portions in a predetermined direction. It will be appreciated that the direction of extension of the differential signal pin contacts is substantially the same as the direction of extension of the shield set contacts 5011. It should be noted that, from the viewpoint of the production process, it is generally understood by those skilled in the art that the shape of the shield plate is designed according to the shape of the signal group 601, that is, the predetermined direction described in the present application, and it is also understood that the signal group contact portion 6011 where the shield plate design is to be disposed extends to form the predetermined direction of the mounting portion.

For the signal group 601 and the shielding group 501, since the contact portion and the mounting portion of the shielding group 501 and the signal group 601 are both present, a conductive material such as copper alloy is usually selected, and in order to improve the conductivity, in an embodiment, tin or lead-tin electroplating may be used.

Illustratively, the number of shield set mounts 5012 and signal set mounts 6012 are matched, and it is understood that the term "matched" as used herein refers to one signal set mount 6012 being disposed between two spaced shield set mounts 5012, and if the signal set 601 is composed of two differential signal pins as shown, then two differential signal pin mounts are disposed between two spaced shield set mounts 5012. That is, with the present application, regardless of the type or number of signal pins constituting the signal group 601, each signal group mounting portion 6012 is necessarily located between two shield group mounting portions 5012 that are spaced apart, i.e., each signal group mounting portion 6012 corresponds to two shield group mounting portions 5012, regardless of the single-ended signal pins, and similarly, the number of shield group contacts 5011 and the number of signal group contacts 6011 are matched.

It can be understood that the differential signal pins of the differential signal group 601 can transmit two signals, the two signals are close and have equal signal amplitudes, the amplitudes of the coupling electromagnetic fields between the two differential signal pins and the ground line are also equal, and at the same time, the electromagnetic fields of the two differential signal pins and the ground line have opposite signal polarities, and therefore, the differential signal pins are more suitable for transmitting signals in a high-speed circuit.

Optionally, the width of each shield set contact 5011 is substantially greater than the width of each differential signal pin contact. The shapes of the contact portions of the differential signal pins and the shield group 501 and the mounting portions thereof are not particularly limited, and optionally, the shield group mounting portion 5012 and the signal group mounting portion 6012 are needle-shaped fish-eye structures having elliptical inner walls for inserting the circuit substrate to be connected. Optionally, the shield set contacts 5011 and the signal set contacts 6011 are straight, see fig. 6, with one and only one contact per shield set contact 5011 and jack shield 80 of the plug.

As mentioned above, the contact portion of the plug contacts with the shielding device correspondingly disposed in the socket to form a loop, and it can be understood that, for the high-speed backplane connector formed by plugging the plug and the socket, the shielding module 5 of the plug and the shielding module 5 of the socket form the integral shielding module 5 of the connector. From the angle of the division of structure, this application promotes the backward flow effect at the plug end of return signal to the improvement of plug shielding module 5, from the angle of whole constitution, improves the backward flow effect of plug end and means improved the holistic shielding effect of connector and the backward flow effect of return signal.

It should be noted that the signal group 601 fitted to the recess space is insulated from the shield substrate 502 and the wing 5016 in the recess space, that is, the signal group 601 is not in electrical contact with the shield substrate 502 or the wing 5016 in the recess space. For example, the width of the signal group 601 is smaller than the distance between the wings 5016 of the adjacent shielding sets 501, and the signal group contacts 6011 are disposed with an insulating spacer at the matching position with the shielding set contacts 5011, see fig. 27, so that the signal group 601 is spaced from the shielding substrate 502, of course, the insulating spacer is a part of the insulating member 60, i.e. the insulating member 60 is pre-disposed with the spacer at the manufacturing time, so that the signal group 601 does not electrically contact with the shielding substrate 502 when the signal group 601 and the shielding plate are mounted. Optionally, in a case that the signal group 601 and the insulating member 60 are integrally formed by injection molding, the signal group 601 is wholly wrapped in the insulating member 60 except for the portions of the contact portion and the mounting portion protruding out of the shielding substrate 502 for respectively matching the plug and the circuit substrate, that is, an insulating spacer always existing between the signal group 601 and the shielding substrate 502, and the insulating spacer may be suspended from the shielding substrate 502 or from the shielding substrate 502. It is understood that, due to the existence of the insulating spacer blocks, the signal group 601 is disposed close to the shielding substrate 502, but is always floating with respect to the shielding substrate 502, i.e., there is no portion electrically contacting with the shielding substrate 502. The signal groups 601 are electrically independent from each other, that is, the signal groups 601 are not connected to each other.

In a second aspect, a differential electrical connection 21 is proposed, comprising a shielding module 5 of the possible embodiments described above, and a set of plug signals 601 cooperating with the shielding module 5. For convenience of description, referring to fig. 14 and fig. 19 to 22, the electrical connection portion a211 is formed by fitting the first shielding plate 51 and the signal group 601; referring to fig. 17 and fig. 23 to 26, the second shield plate 52 is mounted in a matching manner with the signal group 601 to form an electrical connection portion B212. As shown in fig. 30, the aforementioned differential electrical connection portion 21 can also be described as including an electrical connection portion a211, an electrical connection portion B212, and a shield connecting piece 53 for communicating the first shield piece 51 in the electrical connection portion a211 with the second shield piece 52 in the electrical connection portion B212.

Here, each differential signal group 601 of the electrical connection portion a211 and each differential signal group 601 of the electrical connection portion B212 opposite to the electrical connection portion a are differential signal pairs, and as shown in fig. 21 and fig. 25, the signal groups 601 are arranged in two forms, and the first shield plate 51 and the second shield plate 52 of fig. 14 and fig. 17 are respectively mounted correspondingly. It is to be understood that, in the signal group 601 embodiments of fig. 21 and fig. 25, a single-ended signal group 602 is provided, specifically, a single-ended signal group 602 is provided at the leftmost side shown in fig. 20, a single-ended signal group 602 is provided at the rightmost side shown in fig. 21, and the differential electrical connection portion 21 composed of the electrical connection portion a211 shown in fig. 20 and the electrical connection portion B212 shown in fig. 21 is complementary to each other through single-ended signals at two sides.

Therefore, it should be noted that the recess space between adjacent shielding sets 501 for mounting signal sets 601 is described mainly as a recess space, and in connection with the above description of single-ended signals, not all signal sets 601 are disposed in the recess space, that is, not every signal set 601 matches every recess space, but every recess space matches every signal set 601.

It is understood that at the electrical connection portion a211 or B, the shielding group 501 is staggered with the signal group 601, for example, in the form of the shielding group 501, the signal group 601, the shielding group 501, and the signal group 601.

Referring further to fig. 8, 11, 30, 31, respectively, the header includes at least one differential electrical connection portion 21 arranged in the same direction and a header housing 70 housing the differential electrical connection portions 21, with a signal set mounting portion 6012 and a shield set mounting portion 5012 protruding from a top edge of the header housing for plugging onto a circuit substrate.

It should be particularly noted that in the present application, no shield connecting piece 53 is provided between the first shield piece 51 and the second shield piece 52 of the different differential electrical connection portions 21. For example, in the arrangement direction of the differential electrical connection portions 21 on the plug housing 70 shown in fig. 31, there is no shield connecting piece 53 between the second shield piece 52 of the previous differential electrical connection portion 21 and the first shield piece 51 of the subsequent electrical connection portion.

Each differential electrical connection portion 21 can be separately plugged into a socket and complete signal transmission, specifically, a signal group 601 in each differential electrical connection portion 21 is electrically connected with a signal group 601 of the socket to transmit signals, and a shielding group 501 in each differential electrical connection portion 21 is electrically connected with a shielding device of the socket to form a ground shield. It will be appreciated that the number of signal groups 601 and shield groups 501 of the differential electrical connections 21 of the plug correspond to the number of signal groups 601 and shield arrangements in the socket, respectively.

An array of a plurality of the aforementioned differential electrical connections 21 is supported and retained by the plug housing 70. It should be understood that the differential signal pairs may be aligned or staggered; the electrical connection portion a211 and the differential signal pin of the electrical connection portion B212 in the aligned type, i.e. the differential electrical connection portion 21, are in one-to-one correspondence with each other in the arrangement direction shown in the figure, and the electrical connection portion a211 and the differential signal pin of the electrical connection portion B212 in the staggered type, i.e. the differential electrical connection portion 21, have a certain staggered distance in the arrangement direction shown in the figure, for example, the projection portion of the contact portion on the plane where the electrical connection portion B212 is located on the electrical connection portion a211 is located between adjacent contact portions on the electrical connection portion B212, it can be understood that the signal group 601 is disposed between adjacent contact portions, so that the projection portion of the contact portion on the plane where the electrical connection portion B212 is located on the electrical connection portion a211 is overlapped with the signal group 601 on the electrical connection portion B212.

In general, although the differential signal pairs arranged in a staggered manner are less affected by near-end crosstalk and far-end crosstalk, the staggered distance is not as large as possible in consideration of space limitations and the influence of a certain differential signal pair on surrounding differential signal pairs, and needs to be set in accordance with specific situations. As an embodiment of the staggered arrangement: the opposite electrical connection portion a211 and electrical connection portion B212 are opposite to each other along the arrangement direction for only one of the differential signal pins in each differential signal pair, and the other differential signal pin of one of the electrical connection portions is opposite to the shielding group contact portion 5011 of the other electrical connection portion; of course, it is obvious to those skilled in the art that the specific staggered distance of the differential signal pins located at the different electrical connection portions a211 and B212 constituting the differential electrical connection portion 21 can be set according to actual situations.

The plug housing 70 may be formed by injection molding, the material of the insulating member 60 in the plug housing 70 and the differential electrical connection portion 21 depends on the connection manner of the plug and the circuit substrate (backplane or single board), for example, a Surface Mount Technology (SMT) is used to attach the socket, that is, all the shielding group mounting portions 5012 and the signal group mounting portions 6012 are attached to the circuit substrate, the requirement on the heat resistance of the plug housing 70 and the insulating member 60 is high, and a crystalline material such as Liquid Crystal Polymer (LCP) may be used. Or, since it is difficult to form a large heat-resistant bonding region, it is possible to use a pressing method, and optionally, in consideration of cost, it is possible to use a crystalline high-grade engineering plastic, such as SPS (para-polystyrene), for the socket plug housing 70 and the insulator 60 of the electrical connection portion.

In the case where the plug includes a plurality of differential electrical connection portions 21, different differential electrical connection portions 21 may have different signal connection manners, i.e., the differential electrical connection portions 21 are not required to be arranged exactly the same on the receptacle plug housing 70, and thus different differential electrical connection portions 21 may have different numbers of signal group mounting portions 6012, and thus different numbers of shielding group mounting portions 5012, i.e., the number of signal groups 601 and/or shielding groups 501 included in each of the differential electrical connection portions 21 is different. Accordingly, the number of concave spaces formed between the shield groups 501 for fitting the mounting signal group 601 may also be different, so that although the differential electrical connection portions 21 are arranged on the plug housing 70 in one direction, the arrangement of the concave spaces of the adjacent differential electrical connection portions 21 may be staggered; alternatively, the recess spaces for mounting the signal group 601 are the same for different differential electrical connection portions 21, and the adjacent differential electrical connection portions 21 are shifted in the recess spaces in the arrangement direction. Illustratively, without considering the single-ended signal pins of the differential signal pairs, the former differential electrical connection 21 includes 2 signal groups 601 and 3 shield groups 501, and the latter differential electrical connection 21 includes 5 signal groups 601 and 6 shield groups 501; alternatively, the same number of different differential electrical connection portions 21 of the shield group 501 and the signal group 601 are provided, and the shield group 501 and the signal group 601 are distributed at different positions on the different differential electrical connection portions 21.

Optionally, the differential electrical connection portions 21 included in the plug are the same, and the number of the shield groups 501 and the distribution positions on the differential electrical connection portions 21 of the signal group 601 are the same, so that the corresponding shield groups 501, signal group contact portions 6011, shield groups 501, and signal group mounting portions 6012 are the same in number and distribution positions, and the shield groups 501 and the signal groups 601 are arranged on the same plane.

As shown in fig. 32, the dark curve is the near end crosstalk for two pairs of differential signals mated with a shielding module 5 having wings 5016 less than 4mm in length, and the light curve is the near end crosstalk for two pairs of differential signals mated with a shielding module 5 having wings 5016 5mm in length. In the frequency range of 0-20 GHz, the whole dark color curve has less crosstalk than the light color curve, the shielding performance is better, the bandwidth and the quality of signal transmission are effectively ensured, and the method is more suitable for transmission at the speed of 56Gbps and above.

It should be noted that, in the foregoing embodiment, each included module is only divided according to functional logic, but is not limited to the above division as long as the corresponding function can be implemented; also, the terms "horizontal", "vertical", and the like for directional purposes are only used for convenience in describing the relative positions of the components of the present application, and do not limit the present application.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the utility model, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. A shielding module for a high speed backplane connector plug, comprising:

a first shield plate and a second shield plate;

the first shielding sheet and the second shielding sheet respectively comprise a plurality of shielding groups;

each shielding group comprises a contact part electrically connected with the socket, a mounting part formed by extending the contact part along a preset direction and electrically connected with the circuit substrate, and a middle part connecting the contact part and the mounting part;

at least one wing part is arranged in the middle part along the preset direction; the wing part is formed in the middle part, one end of the wing part is fixed on the middle part, and the other end of the wing part is separated from the surface of the middle part and is bent to a preset height relative to the surface of the middle part; the concave space defined by the surfaces of the opposite wing parts and the middle parts on every two adjacent shielding groups is used for placing the plug signal group;

the middle parts of all the shielding groups contained in the first shielding sheet are positioned on the same shielding substrate;

the middle parts of all the shielding groups contained in the second shielding sheet are positioned on the same shielding substrate;

the contact portion includes a first side in electrical contact with the receptacle shield set, and a second side opposite the first side;

the second side surface of the contact part in the first shielding sheet is opposite to the second side surface of the contact part in the second shielding sheet;

the shielding module further comprises a shielding connecting piece, the shielding connecting piece is located between the second side face of the contact part in the first shielding piece and the second side face of the contact part in the second shielding piece, one side of the shielding connecting piece is electrically interconnected with the second side faces of all the contact parts in the first shielding piece, the other side of the shielding connecting piece is electrically interconnected with the second side faces of all the contact parts in the second shielding piece, and two sides of the shielding connecting piece are communicated.

2. The shielding module of claim 1, wherein the shield tabs are electrically interconnected to each second side by any one of metal spring interconnections, conductive glue, or plastic plating.

3. The shielding module according to claim 2, wherein a projection of the contact portion of the first shielding plate on the surface on which the second shielding plate is located between the contact portions of the second shielding plates.

4. The shielding module of claim 3, wherein the shield connecting plate includes spring plates having two sides electrically contacting the second side surface and a base portion connecting the two spring plates, the spring plates at the two sides respectively press against the second side surface of the first shielding plate and the second side surface of the second shielding plate.

5. A shielding module according to claim 2 or 4, characterized in that the direction of the force exerted by the shield connecting piece by the first shield piece is opposite to the direction of the force exerted by the second shield piece.

6. The shielding module of claim 5, wherein the interconnection point of the shield tabs to the second side is located below the contact point of the first side of the contact portion to the shielded set of receptacles in the direction of insertion of the plug into the receptacle.

7. The shielding module of claim 1, wherein the length of the wings is different for different sets of shielding, the maximum length of the wings being less than 4 mm.

8. The shielding module of claim 7, wherein the wing portion has a slit, and a line of the slit is undulated along the arrangement direction of the shielding assembly on the same first shielding plate or the same second shielding plate.

9. A differential electrical connection portion of a high-speed backplane connector plug, comprising the shielding module of claim 3, and further comprising a signal group spatially fitted in the recess, and an insulating member fitted in the signal group, the signal group including a contact portion and a mounting portion in which the contact portion extends in the predetermined direction; the signal group is insulated from the shield substrate.

10. A high speed backplane connector plug comprising at least one differential electrical connection of claim 9 and a plug housing for receiving said differential electrical connection.

Images