This disclosure relates to the field of input/output (“IO”) connectors, more specifically to the field of high data-rate capable IO connectors.
IO connectors are commonly used to support network and server applications. Known IO connectors include SFP, QSFP, CXP and XFP style connectors, just to name a few. One issue that has resulted from the existing styles of connectors is that each style is popular for particular applications. SFP connectors are 1× connectors (supporting one transmission channel and one receive channel) and suitable for applications where a single channel of communication is sufficient. CXP is a 12× connector and is desirable when many more channels of communication are needed. QSFP is a 4× connector and thus is a popular choice for many applications as it provides sufficient bandwidth and front panel density to meet a wide range of applications. Thus QSFP connectors have become a preferred style for number of applications. An embodiment of a QSFP-style plug assembly 10 (as shown in
While QSFP style connectors are suitable for many applications, it would be desirable to offer greater front panel density. New connector designs at smaller pitches are being proposed and should help satisfy these needed in a wide range of applications. However, a substantial number of cable assemblies, including passive and active cable assemblies, exist for the QSFP style connector and it would be beneficial to avoid the need to scrap prior designs. Accordingly, certain individuals would appreciate a way to offer increased front panel density while maintaining compatibility with existing QSFP designs.
A receptacle assembly is disclosed that includes a connector inside a cage. The connector includes a first connection region and a second connection region and each connection region includes opposing rows of terminals. One of connection regions can be configured to mate with a single row of pads and be compatible with the mating blade of a standard connector. The combination of the first and second connection regions can be configured to mate with a higher density plug assembly that includes mating blade configured with two rows of pads. The receptacle assembly can be stacked and provide two ports and each port can include a module that supports two connection regions. The cage can be configured to airflow through the cage so as to improve cooling of any inserted plug assemblies.
A plug assembly is disclosed that includes a body with a top flange, a bottom flange and a mating blade positioned between the two flanges. A first row and a second row of pads can be provided on two sides of the mating blade. The top flange has a bottom surface that faces toward the circuit card and includes first and second level, the first level being closer to the mating blade than the second level. The bottom flange that is substantially shorter than a circuit card and can be configured so that the bottom flange covers one row of pads while not covering the second.
In operation, the connector system can provide backward compatibility between the receptacle assembly and existing plug assemblies while enabling higher density connections between the receptacle assembly and plug assembly configured for increased data throughput. In some embodiments the connector system can be a QSFP style connector.
The present disclosure is illustrated by way of example and not limited in the accompanying figures in which like reference numerals indicate similar elements and in which:
The detailed description that follows describes exemplary embodiments and is not intended to be limited to the expressly disclosed combination(s). Therefore, unless otherwise noted, features disclosed herein may be combined together to form additional combinations that were not otherwise shown for purposes of brevity.
The disclosed embodiments illustrates features that can be included in a high density QSFP style connector system. As can be appreciated, while a stacked receptacle assembly is disclosed that includes a top port and a bottom port, a single port connector could also be provided. In addition, ganged version could also be provided by increasing the number of connectors depicted and creating a cage that had two or more ports arranged side by side. It should be noted that while the depicted embodiment is configured to be compatible with a QSFP style connector, this disclosure is not so limited. Other known standards, such as SFP or XSFP or new standards would also be compatible with the features and discussion provided herein and the style of connector is not intended to be limiting unless otherwise noted.
As can be appreciated, the receptacle assembly includes a two-part housing. A first set of wafers support vertical terminals. The vertical terminals include tails but do not include contacts. A second set of wafers support horizontal terminals. The horizontal terminals include contacts but do not include tails. The first and second sets of wafers are pressed together so that there is an electrical connection between the tails and the contacts.
The system is designed so that it supports 25 Gbps data rates for each differential channel and thus offers the ability to support 200 Gbps systems, compared to existing QSFP systems that can support 100 Gbps with a 25 Gbps differential channel.
As can be appreciated, the receptacle assembly is configured to improve air flow so that the system can be cooled while still supporting light pipes. A center member includes an open channel that allows air to flow between a top and bottom port. The center member includes a center divider and apertures in two side walls. A back wall of a cage can includes apertures that allow air to flow in (or out, depending on whether the airflow is front-to-back or back-to-front) of the connector in an efficient manner.
Turning to
The top flange 60 includes a first lower surface 60a and a second lower surface 60b and the first lower surface 60b is offset from the second lower surface 60b. Thus the first distance between the first lower surface 60a and the mating blade 70 is less than a second distance between the second lower surface 60b and the mating blade.
The mating blade 70 includes a top surface 70a that supports a first pad row 72, a second pad row 74 and a third pad row 76 that are positioned between the first and second rows of pads 72, 74. The mating blade 70 also includes a bottom surface 70b that supports a fourth pad row 72′, a fifth pad row 74′ and a sixth pad row 76′ that are positioned between the first and second rows of pads 72′, 74′. As can be appreciated, the fourth, fifth and sixth pad rows can be arranged the same as the first, second and third pad rows but are positioned on the opposite side of the mating blade 70. In an embodiment the top flange 60 can cover the first, second and third pad rows 72, 74, 76 and can extend past the front end 77 while the bottom flange 65 covers just the fifth pad row 74′ on the bottom. While not required, one potential advantage of such a configuration is that it allow the plug assembly to be interchangeable with a system that allows for two different plug assemblies to be alternatively inserted into the same port, as will be disclosed below.
The first row 72 include short pads 82 that can be configured as signal pads for higher data rates and longer pads 81 that can be used as ground pads or low data rate pads. As shown, the short pads 82 are arranged so as to provide a differential pair 83. In operation, the first pad row 72 will slide past a second connection region 174 and mate with a first connection region 172 while the second pad row 74 mate with the second connection region (as will be discussed below). To ensure the connection with the first and second connection regions 172, 174 are reliable it has been determined beneficial to include the third pad row 76 to protect the first connection region. The third pad row 76 can include long pads 84 positioned between two pairs of short pads and further include intermediate pads 85 positioned between long pads 81. Naturally, the depicted configuration is intended to have the first pad row 72 and second pad row 74 be configured substantially the same. If such a configuration is not required then the third pad row 76 may have a different configuration of pads. Regardless, it is preferred that the pads in the third pad row 76 be longer than the short pads 82 in the first and second pad rows 72, 74 so as to ensure good electrical separation between the first and second pad rows 72, 74.
It should be noted that the plug assembly is depicted as a copper-based configuration but could readily be provided as a copper/optical solution (e.g., a transceiver). In such a configuration the internal part of the plug would include a desired optical engine (such as is available from OPLINK or other providers) and would convert the copper signals to optical signals and would be configured to transmit those optical signals over optical fibers, as is known.
As can be appreciated from
In order to define the two ports more fully, a divider 190 is positioned between the top port 110 and the bottom port 115. The divider 190 includes a first wall 191 and a second wall 192. The first wall 191 that helps define the top port 110 and the second wall 192 helps define the bottom port 115. The divider 190 also provides a channel for air to flow between the ports in direction B-B so that air can flow pass through front vents 107 in center wall 106 (path A-A) or through rear vents (path C-C), through path B-B and then through path C-C or AA. If the vents 136 are provided then another path of air through the vents is also possible. More will be said about the air flow below.
The connector 150 includes a first module 160 and a second module 165 that respectively provide the mating contacts positioned in the top and bottom ports 110, 115. It should be noted that each of the modules 160, 165 are depicted as being different because in some embodiments it will be desirable to connect terminals 230 (or some of the terminals 230) to the supporting circuit board. Thus, as depicted the first module 160 includes a first terminal row 181 supported by a frame 181a, a second terminal row 182 supported by a frame 182a, a third terminal row 183 supported by a frame 183a and a fourth terminal row 184 supported by a frame 184a. In a similar fashion, the second module 165 provides a first terminal row 186 supported by frame 186a, a second terminal row 187 supported by a frame 187a, a third terminal row 188 supported by a frame 188a and a fourth terminal row 189 supported by a frame 189a. Each of the frames can include cutouts 198 to modify the impedance of the terminal.
The depicted terminals 230 have different lengths but generally have a contact 231, a cantilevered portion 231a, a wide body portion 232a, a narrow body portion 232b and a tail 233. The depicted tail 233 is configured to be pressed on a mating terminal as will be discussed below but could also be configured to be attached to a conductor of a cable assembly. For example, as shown in
Each module 160, 165 provides two connection regions. Specifically, module 160 includes first connection region 172 and second connection region 174 while module 165 includes first connection region 172′ and second connection region 174′. The first connection region is provided by contacts in by the first terminal row 181 and in the second terminal row 184 (which provide rows of opposing contacts) while the second connection region is provided by contacts in the second terminal row 182 and the third terminal row 183 (which again provide row of opposing contacts). As can be appreciated, two terminal rows (the depicted terminal rows 186 and 187 in
In operation, a plug assembly can be inserted into the top port 110 and a mating blade will engage the second connection region 174. If the plug assembly is a standard design then the mating blade has a single pad row that will only engage the second connection region. If the plug assembly has two pad row design (e.g., a high density design) then the first pad row on the mating blade will first engage the second connection region and then as the plug assembly is fully inserted into the port, the first pad row will slide past the second connection region 174 and engage the first connection region 172. Accordingly, for a plug assembly with two pad rows of signal contacts on each side, the first pad row 72 will engage the first connection region 172 while the second pad row 74 will engage the second connection region 174. If desired the first connection region 172′ and second connection region 174′ can be similarly configured and can operate similarly. This can be appreciated from
As previously noted, the top flange 60 includes the first lower surface 60a and the second lower surface 60b. The modules 160, 165 are configured to support a nose portion 320a, 320b and the nose portions include a first nose surface 323a that is configured to be aligned with the first lower surface 60a and may include a nose wall 323b that provides a transition to a second nose surface 323c that is aligned with the second lower surface 60b.
As can be appreciated, the connector 150 includes a first card slot 331 aligned with the top port 110 and a second card slot 332 aligned with the bottom port 115. The card slots 331, 332 are recessed away from the front face 116, in an embodiment the cage has a length L and the cards slots are recessed a distance that is at least ⅓ L. The connector also includes a top air path 345 that provides for a ventilation path in the top port. In order to improve cooling in the bottom port 115, a center member 340 is provided. The center member 340 can be positioned between a first nose portion 320a that defines the first card slot 331 and a second nose portion 320b that defines the second card slot 332. The center member 340 include outer walls 340a, 340b that each include side vents 342, the center member 340 further includes a center wall 341 that helps split and direct the air passing through the divider 190 toward the two outer walls 340a, 340b. Because the outer walls 340a, 340b are recessed in compared to the cage, the space between the outer walls 340a, 340b, the side walls 135 and the shoulders 321, 322 of respective nose portions 320a, 320b creates an air channel 344 that allow air to flow past the connector 150 and out through the rear vents 139.
The top air path 345 accepts a rear section 346 that can be mounted to the top air path 345 and extends the air path toward the rear wall 138. The second nose portion 320b can be connected to back bracket 352, which can help provide for additional rigidity. It should be noted however, that the first nose portion 320a and second nose portion 320b do not need to be a single structure and thus can be separately attached to the respective module and supported by the center member 340. As can be appreciated, the depicted nose portions 320a, 320b include terminal grooves 326 that help support the contacts with a comb-like structure. While terminal grooves 326 are not required it is beneficial to provide them for the connection region that makes the first contact with a mating blade being inserted in the I direction.
In order to mount the modules 160, 165 on a circuit board, vertical modules 205, 210 are provided. The depicted vertical modules provide a stepped configuration, as can be appreciated from
It should be noted that while a stacked configuration is shown, a single port configuration is also contemplated. For example, the module 165 and the vertical module 210 could be used by themselves to provide a single port design (as compared to a stacked configuration). In such a configuration a single nose portion could be used and the center module could be omitted. It should also be noted that while a press-fit configuration is depicted, a version design for SMT mounting is also contemplated and within the scope of the disclosure as a person of skill in the art would generally be able to replace a standard press-fit tail with an SMT tail.
Regardless of the mounting type, assuming there is a mounting to circuit board, terminals 230 are connected to vertical terminals 290. The depicted vertical terminals 290 include a tail 291, a shoulder 292 and a vertical riser 293 that is configured to engage the tail 233. As depicted, the engagement is an interference fit between the vertical riser 293 and an aperture 233a.
The disclosure provided herein describes features in terms of preferred and exemplary embodiments thereof. Numerous other embodiments, modifications and variations within the scope and spirit of the appended claims will occur to persons of ordinary skill in the art from a review of this disclosure.
Number | Date | Country | |
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62222310 | Sep 2015 | US |
Number | Date | Country | |
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Parent | 18137450 | Apr 2023 | US |
Child | 18801871 | US | |
Parent | 16194606 | Nov 2018 | US |
Child | 18137450 | US | |
Parent | 15761870 | Mar 2018 | US |
Child | 16194606 | US |