The subject matter herein relates generally to socket connectors, and more particularly, to power plates for socket connectors.
Electronic devices, such as computers, workstations and servers, may use numerous types of electronic modules, such as processors and memory modules (e.g. Dynamic Random Access Memory (DRAM), Synchronous Dynamic Random Access Memory (SDRAM), Double Data Rate (DDR) SDRAM, DDR2 SDRAM, DDR3 SDRAM, DDR4 SDRAM, or Extended Data Out Random Access Memory (EDO RAM), and the like). The memory modules are produced in a number of formats such as, for example, Single In-line Memory Module (SIMM), or Dual In-line Memory Modules (DIMM). Typically, the memory modules have a circuit board that is installed in a multi-pin socket connector mounted on a system board or motherboard. Each memory module has a card edge that provides an interface generally between two rows of contacts in the socket connector. The memory modules include memory devices mounted on the circuit board that store data for the electronic device. The memory devices require power to operate, and the power is supplied to the memory devices by the contacts within the socket connector.
Known electronic devices having memory modules are not without disadvantages. For instance, the power requirement to operate the memory devices has increased over time as the electronic devices are designed to operate more quickly and/or as the amount of data being stored by the memory devices is increased. The mating interface between the system board and the socket connector is a bottleneck for transfer of power to the memory modules. For example, voltage tolerances are becoming tight at high speeds as voltage levels are dropping and the current used by the memory modules is rising. The voltage drop on the power contacts is particularly problematic as the current for the memory modules is changing at a high differential from, for example, a low static power to a high active charging power. Another factor affecting the powering problem is that voltage regulation is typically performed by a voltage regulator upstream of the socket interface before the power flows through the socket connector to the memory card. High inductance for the power path is pan of the problem as well as resistance, voltage regulation point, and the number of memory modules per voltage regulator.
In one embodiment, a socket connector is provided including a housing having a mating interface configured to mate with an electronic component and a mounting interface configured to mount to a circuit board. Signal contacts are held by the housing and extend between the mating interface and the mounting interface. Power contacts are held by the housing and extend between the mating interface and the mounting interface. The power contacts are configured to transmit power from the circuit board to the electronic component. Each of the power contacts have at least one commoning element. A metallic power plate is coupled to the commoning elements of a plurality of the power contacts to electrically common the power contacts to one another.
In another embodiment, a socket connector is provided that includes a housing having a mating interface configured to mate with an electronic component and a mounting interface configured to mount to a circuit board. Signal contacts are held by the housing and extend between the mating interface and the mounting interface. Power contacts are held by the housing and extend between the mating interface and the mounting interface. The power contacts are configured to transmit power from the circuit board to the electronic component. Each of the power contacts have at least one commoning element. A power plate is coupled to the commoning elements of a plurality of the power contacts to electrically common the power contacts to one another. The power plate is loaded onto the commoning element and secured to the power contact by an interference engagement with the commoning element.
In a further embodiment, a socket connector is provided including a housing extending along a connector axis, signal contacts held by the housing that are parallel to one another and spaced apart along the connector axis, and power contacts held by the housing that are parallel to one another and spaced apart along the connector axis. Each of the power contacts includes at least one commoning element. A power plate extends along a plate axis generally parallel to the connector axis. The power plate has a band extending along the plate axis and a plurality of arms extending outward from the band in a direction generally perpendicular to the plate axis. The power plate is coupled to the commoning elements of a plurality of the power contacts to electrically common the power contacts to one another. Adjacent arms engage different power contacts.
The memory system 16 stores data for the electronic device 14. The electronic device 14 may be any type of electronic device such as, for example, a computer, a workstation, a server, and the like. The electronic device 14 may include one or more electronic modules 18, such as a processor. Optionally, the electronic module 18 may be connected with the memory system 16. For example, the electronic module 18 may be electrically connected to a motherboard or system board 20. The electronic device 14 may also include one or more power sources 22. Optionally, the power source 22 may be connected with the memory system 16. For example, the power source 22 may be electrically connected to the system board 20.
In an exemplary embodiment, the memory system 16 includes one or more electronic components in the form of memory modules 24 mounted to corresponding socket connectors 12. Other types of electronic components may be connected by the connector system 10 in alternative embodiments. The memory module 24 may constitute a Synchronous Dynamic Random Access Memory (SDRAM) module. Optionally, the memory module 24 may be a Dual In-line Memory Module (DIMM module). Any number of memory modules 24 and socket connectors 12 may be provided within the memory system 16. Additionally, any number of memory systems 16 may be, provided within the electronic device 14.
In an exemplary embodiment, the memory module 24 is electrically connected to one or more data devices, such as the electronic module 18, for sending data thereto and/or receiving data therefrom. The memory module 24 stores data generated by the data device and/or sends stored data to the data device. Optionally, the memory module 24 may be connected to the data device via the system board 20. For example, the data device may be coupled directly to the system board 20, or alternatively, may be provided remote from the system board 20 and connected thereto by an electrical connection. The memory module 24 is electrically connected to one or more power source 22 for powering the memory module 24. The memory module 24 may be connected to the power source 22 via the system board 20. The power source 22 may be directly coupled to the system board 20, or alternatively, may be provided remote from system board 20 and connected thereto by an electrical connection.
The memory module 24 includes a circuit board 32 and a plurality of memory devices 34 coupled to the circuit board 32. The memory devices 34 may be integrated circuit (IC) chips or other electronic components for storing data. Any number of memory devices 34 may be electrically connected to the circuit board 32. In the illustrated embodiment, eight memory devices are mounted to a first side 36 of the circuit board 32. Memory devices 34 may also be mounted to a second side 38 of the circuit board 32.
The memory module 24 is electrically connected to the system board 20 by the socket connector 12. In the illustrated embodiment, the socket connector 12 constitutes a card edge connector having a slot 40 that receives the memory module 24 therein. A plurality of socket contacts are arranged in one or more rows within the slot 40 for mating with the memory module 24. For example, the socket connector 12 may include upper socket contacts 42 and lower socket contacts 44 that mate with contact pads 46 arranged at an edge 48 of the circuit board 32 when the circuit board 32 is plugged into the card edge slot 40. The upper socket contacts 42 are arranged in an upper row along one side of the slot 40 and the lower socket contacts 44 are arranged in a lower row along another side of the slot 40 generally opposite to the upper socket contacts 42.
The socket connector 12 holds the circuit board 32 of the memory module 24 parallel to the system board 20. For example, the system board 20 may have a generally horizontal orientation and the circuit board 32 may also have a generally horizontal orientation at a spaced apart position either above or below the system board 20. Such a configuration defines a low profile connector system 10 with respect to the system board 20 because the overall height of the connector system 10 is the same as the height of the socket connector 12. The memory module 24 does not extend above the socket connector 12. Alternatively, the socket connector 12 may be configured to orient the circuit board 32 at a right angle with respect to the system board 20. For example, the system board 20 may have a generally horizontal orientation and the circuit board 32 may have a generally vertical orientation. In such configuration, two rows of socket contacts are provided on either side of the vertically extending slot. Each row of socket contacts may have both power and signal contacts. As described below, the power contacts in both rows may be electrically commoned together. In an exemplary embodiment, the system board 20 relays both power and data, represented by power and data paths 50, 52, respectively, to and/or from the memory module 24 via the socket connector 12.
Optionally, one or more voltage regulator modules 54 may be electrically connected to the system board 20. The voltage regulator modules 54 control the flow of power along the power path 50. The voltage regular module 54 includes a plurality of components, such as resistors, capacitors, traces and/or contacts, that are part of a power circuit for controlling the flow of power to the memory module 24. The components manipulate the power coming into the voltage regulator module 54 such that the power output has different power characteristics than the power input. For example, the power circuit may control and/or regulate a voltage, a current, or another power characteristics of the power output.
The socket connector 12 includes a housing 60 having a mounting interface 62 at a bottom of the socket connector 12 that is mounted to the system board 20. The housing 60 includes a mating interface 64 defined at the front of the socket connector 12 for mating with the memory module 24. The front is oriented at a right angle with respect to the bottom. The slot 40 is open along the front for receiving the memory module 24. The socket contacts 42, 44 may have a predetermined contact pattern for mating with a particular type of memory module 24. The upper socket contacts 42 are generally arranged at a rear of the housing 60, generally opposite the mating interface 64, and extend into the slot 40. The lower socket contacts 44 are generally arranged at a front of the housing 60 and extend into the slot 40 to define part of the mating interface 64. Optionally, a subset of the upper and/or lower socket contacts 42, 44 may define power contacts 72 and another subset of the socket contacts 42, 44 may define signal or data contacts 74. The socket contacts 42, 44 may define other types of contacts as well, such as ground contacts. The power contacts 72 transmit the power routed by the system board 20 to the memory module 24. The data contacts 74 transmit the data between the system board 20 and the memory module 24. In an alternative embodiment, the power contacts 72 may be structurally different than the data contacts 74. For example, the power contacts 72 may have a different size and shape and/or the power contacts 72 may be made from a different material or have a different coating.
The housing 60 extends along a connector axis 102 between opposed sides of the housing 60. The top, bottom, front and rear of the housing 60 are parallel to the connector axis 102. The connector axis 102 is the longitudinal axis of the socket connector 12. The power plates 100 define the secondary power or current paths that are oriented generally perpendicular to the connector axis 102.
Each power plate 100 includes a metallic body extending between an upper end 104 and a lower end 106. The power plate 100 has a width defined between the upper end 104 and the lower end 106. The secondary power path provided by the power plate 100 is defined generally along the width of the power plate 100 between the upper and lower ends 104, 106. The power plate 100 is convex with the upper and lower ends 104, 106 engaging the power contacts 72. A central portion 108 of the power plate 100 is bowed outward from the upper and lower ends 104, 106 to give the power plate 100 a convex shape. When the power plate 100 is connected to the power contacts 72, the central portion 108 may be deflected and flexed toward the power contacts 72. The power plate 100 includes a plurality of openings 109 at the central portion 108. The openings 109 receive portions of the power contacts 72 to secure the power plate 100 to the power contacts 72.
The socket contacts 42 extend between, and define a portion of, the mounting interface 62 and the mating interface 64 of the socket connector 12. Each signal contact 74 includes a contact tail 110 at the mounting interface 62 for mounting to the system board 20 (shown in
Each signal contact 74 includes a contact base 112 extending perpendicular from the mounting interface 62 along the rear of the housing 60 (shown in
Each power contact 72 includes a contact tail 120 at the mounting interface 62 for mounting to the system board 20. Optionally, the contact tail 120 may be surface mounted to the system board 20, such as by soldering to the system board 20. Alternatively, the contact tail 120 may be through hole mounted to a via in the system board 20. Each power contact 72 includes a contact base 122 extending perpendicular from the mounting interface 62 along the rear of the housing 60. The contact base 122 extends from the contact tail 120 to a contact beam 124, which extends from the contact base 122. Optionally, the contact beam 124 may extend generally perpendicular from the contact base 122. Alternatively, the contact beam 124 may extend at a non-perpendicular angle from the contact base 122. The contact beam 124 is exposed within the slot 40 at the mating interface 64 for mating with the circuit board 32.
The power contact 72 includes at least one commoning element 126. The power plate 100 (shown in
The power plate 100 is convex in shape with the upper and lower ends 104, 106 extending from the central portion 108. During assembly, the central portion 108 is pushed inward toward the power contact 72, which forces the upper and lower ends 104, 106 to deflect relative to the central portion 108, such as in the directions of arrows A and B, respectively. When the upper and lower ends 104, 106 are deflected, the ends 104, 106 are biased against the power contact 72 and held against the commoning elements 128, 132 by an interference engagement caused by the spring force of the power plate 100 against the power contact 72. The central portion 108 is held in place by the interference engagement with the central commoning element 130. Alternatively, the power plate 100 may be held in position by another component, such as a cover (not shown) that is secured to the rear of the housing 60 (shown in
The power plate 100 provides a parallel current path from the upper portion of the power contacts 72 to the lower portion of the power contacts 72. In an exemplary embodiment, the power plate 100 has a high conductivity and/or a low resistance. The power plate 100 is placed in close proximity to all the corresponding power contacts 72 to provide a lower inductance for the socket connector 12. The power plate 100 makes connection to both the top and bottom of as many, and potentially all, of the power contacts 72. Connecting to multiple power contacts 72 provides a low resistance current path for each of the power contacts 72 that is in parallel to the power paths of each of the other power contacts 72, which provides a total resistive path that is much lower than the power contacts 72 alone. The power plate 100 is in close proximity to each of the other power contacts 72 to help lower the total power contact inductance, which will help reduce voltage drop through the socket connector 12 during high transient power switching times. By lowering the resistance and/or the inductance, the performance of the socket connector 12 is increased.
Some of the differences between the socket connector 200 and the socket connector 12 are that the socket connector 200 includes socket contacts 210 that differ from the socket contacts of the socket connector 12. The socket contacts 210 may constitute both power contacts 212 and signal contacts 214. Optionally, only the power contacts 212 differ from the power contacts 72 (shown in
The power plates 202 are connected to the power contacts 212 to electrically common a plurality of the power contacts 212 to one another. The power plates 202 define secondary power or current paths between the top and the bottom of the power contacts 212 that is parallel to the power path defined by the power contacts 212. In the illustrated embodiment, multiple power plates 202 are provided that electrically common different subsets of the power contacts 212 together. Any number of power plates 202 may be utilized, depending on the particular application.
The housing 208 extends along a connector axis 216 between opposed sides of the housing 208. The top, bottom, front and rear of the housing 208 are parallel to the connector axis 216. The connector axis 216 is the longitudinal axis of the socket connector 200.
Each power plate 202 includes a metallic body extending between an upper end 218 and a lower end 220. The power plate 200 is convex with the tipper and lower ends 218, 220 engaging the power contacts 212. A central portion 222 of the power plate 202 is bowed outward from the upper and lower ends 218, 220 to give the power plate 202 a convex shape. When the power plate 202 is connected to the power contacts 212, the central portion 222 may be deflected and flexed toward the power contacts 212. The power plate 202 is folded over at the upper and lower ends 218, 220 to define clips 224 at the upper and lower ends 218, 220. The clips 224 engage portions of the power contacts 212 to secure the power plate 202 to the power contacts 212.
The power contact 212 includes at least one commoning element 236. The power plate 202 (shown in
The power plate 202 is convex in shape with the upper and lower ends 218, 220 extending from the central portion 222. During assembly, the central portion 222 is pushed inward toward the power contact 212, which forces the upper and lower ends 218, 220 to deflect relative to the central portion 222, such as in the directions of arrows C and D, respectively. Optionally, one of the clips 224 may be placed on the corresponding commoning element 238, 240 and then the central portion 222 pushed inward to widen the power plate 202 such that the other clip 224 may be placed over the other commoning element 238, 240. The central portion 222 is held in place by the interference engagement with the upper and lower mounting tabs 238, 240. Alternatively, the power plate 202 may be held in position by another component that holds the power plate 202 in physical contact with the power contact 212. When the upper and lower ends 218, 220 are deflected outward, the power plate 202 is straightened from the initial concave shape to a final shape, such as the shape illustrated in
The power plate 202 provides a parallel current path from the upper portion of the power contacts 212 to the lower portion of the power contacts 212. In an exemplary embodiment, the power plate 202 has a high conductivity and/or a low resistance. The power plate 202 is placed in close proximity to all the corresponding power contacts 212 to provide a lower inductance for the socket connector 200 (shown in
The power plates 302 are connected to the power contacts 72 to electrically common a plurality of the power contacts 72 to one another. The power plates 302 define a secondary power or current path between the top and the bottom of the power contacts 72 that is parallel to the power path defined by the power contacts 72. In the illustrated embodiment, multiple power plates 302 are provided that electrically common different subsets of the power contacts 72 together. Any number of power plates 302 may be utilized, depending on the particular application.
Each power plate 302 includes a metallic body extending between an upper end 304 and a lower end 306. The power plate 302 is convex with the upper and lower ends 304, 306 engaging the power contacts 72. A central portion 308 of the power plate 302 defines a band 310 that extends between opposed sides 312 of the power plate 302.
A plurality of upper arms 314 extend from a top of the band 310 to the upper end 304 of the power plate 302 and a plurality of lower arms 316 extend from a bottom of the band 310 to the lower end 306 of the power plate 302. Alternatively, the arms only extend from either the top or the bottom of the band 310 such that only upper arms 314 or only lower arms 316 are provided.
Adjacent arms 314 are separated by a slit 318 such that the arms 314 are capable of moving independently with respect to one another. The slits 318 may be very narrow such that the arms 314 essentially touch one another. Alternatively, the slits 318 may be wide such that the arms 314 are separated from one another by a noticeable gap. The slits 318 may be cut into the power plate 302 after the power plate 302 is formed. Alternatively, the slits 318 may be formed simultaneously with the power plate 302, such as during a stamping process and prior to forming the power plate 302.
The central portion 308 of the power plate 302 is bowed outward such that the band 310 is positioned outward with respect to the upper and lower ends 304, 306 to give the power plate 302 a convex shape. When the power plate 302 is connected to the power contacts 72, the band 310 may be pushed inward toward the power contacts 72.
The band 310 includes a plurality of openings 320 that receive the central commoning elements 130 to secure the power plate 302 to the power contacts 72. During assembly, the arms 314, 316 are placed against the outer edge of the power contacts 72 and the band 310 is pushed inward toward the power contact 72 to load the central commoning elements 130 through the openings 320. The band 310 is held in place by an interference engagement with the central commoning elements 130. Alternatively, the power plate 302 may be held in position by another component, such as a cover (not shown) that is secured to the rear of the housing 60 (shown in
Because the arms 314, 316 are capable of moving independently, the arms 314, 316 accommodate changes in positions of the commoning elements 126. For example, the positions of the commoning elements 126 may vary due to manufacturing tolerances of the housing 60 and/or of the power contacts 72. Additionally, the positions of the commoning elements 126 may vary due to improper assembly, such as by not fully loading the power contacts 72 into the housing 60 or by overloading the power contacts 72 into the housing 60, which changes the relative positions of the outer edge of the power contacts 72. The arms 314, 316 accommodate the variations in positions of the power contacts 72 to ensure physical contact with each of the power contacts 72.
It is to be understood that the above description is intended to be illustrative, and not restrictive. For example, the above-described embodiments (and/or aspects thereof) may be used in combination with each other. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from its scope. Dimensions, types of materials, orientations of the various components, and the number and positions of the various components described herein are intended to define parameters of certain embodiments, and are by no means limiting and are merely exemplary embodiments. Many other embodiments and modifications within the spirit and scope of the claims will be apparent to those of skill in the art upon reviewing the above description. The scope of the invention should, therefore, be determined with reference to the appended claims, along with the full scope of equivalents to which such claims are entitled. In the appended claims, the terms “including” and “in which” are used as the plain-English equivalents of the respective terms “comprising” and “wherein.” Moreover, in the following claims, the terms “first,” “second,” and “third,” etc. are used merely as labels, and are not intended to impose numerical requirements on their objects. Further, the limitations of the following claims are not written in means—plus-function format and are not intended to be interpreted based on 35 U.S.C. §112, sixth paragraph, unless and until such claim limitations expressly use the phrase “means for” followed by a statement of function void of further structure.