Patent Description:
A datacenter comprises several high-performance computing cabinets, called HPC cabinets or "clusters", arranged in rows within the datacenter and configured to house computing units, such as servers, switches and routers, to organize, process and store data. Each computing unit comprises conventionally at least one mother board and several components secured to the mother board such as processors, Dual In-Line Memory Module (DIMM), a PCle component (GPU, FPGAs)), fans, etc..

High performance computing has gained importance in recent years by several industries which are trending towards increasing sizes or combinations of two or more servers to achieve faster processing performance for a large number of processing operations. Solutions known to address such requirement of the industries include Ultra Path Interconnect (UPI) technology which provides a scalable multiprocessor system, for example, by linking motherboards of two or more computing units together. However, users face several issues which either require a maintenance activity to be carried out on the computing units and may often include replacement of few components in the computing units.

A HPC cabinet comprises traditionally two vertical side walls delimiting a central cavity with a front opening, so as to define vertically stacked sockets having a standard height (U). A computing unit is configured to be housed in the HPC cabinet and mounted onto the two vertical side walls. The height of the computing device is usually comprised between 1U and 6U.

Each vertical side wall comprises a front portion which is configured to cooperate with an abutment wall of the computing unit. Usually, the front portion of each side wall comprises threaded openings and the abutment wall of the computing unit comprises screws which are configured to be screwed into the threaded openings so that the computing unit is secured fixedly to the HPC cabinet. Besides its mechanical mounting, each computing unit is also connected to a power distribution unit, known as PDU, and to a network thanks to a management node (not represented) located within the HPC cabinet.

<CIT> relates to an apparatus for interfacing motherboard with multiple expansion cards used for audio processing, video processing and networking, has chassis that is provided with motherboard slot, where midplane is provided with motherboard socket.

<CIT> relates to a holding component with a riser card for receiving an expansion component for a computer system.

A computing unit comprises generally a bottom tray on which are mounted the components and a top tray comprising ventilation ducts so that fresh air, coming from the front, can be delivered to the rear of the computing unit.

The bottom tray can receive several components such as expansion cards comprising a GPU (Graphical Processing Unit). However, the expansion cards are becoming larger. The FHFL format (Full Height Full Length) is becoming more and more popular. In current computing units, it is not possible to mount at the same time processors, memory cards and expansion cards.

In order to overcome such a drawback, a first solution would be to provide a computing unit dedicated for receiving FHFL expansion cards but it is uneconomic. A second solution would be to increase the height of the computing unit in order to mound the expansion cards vertically. Such a solution would decrease the number of computing units which can be mounted in a HPC cabinet, which is a drawback for customers.

Accordingly, it is one object of the present disclosure to provide a computing unit in which a FHFL expansion card can be mounted and replaced effortlessly.

The invention relates to a computing unit configured to be mounted in a High-Performance Computing cabinet, thereafter HPC cabinet, defining a plurality of vertically stacked sockets, the computing unit comprising:.

Thanks to the invention, the top tray is used for guiding air flow but also for mounting top secondary electronic components which are very large such as FLFH format. The top tray is connected electronically to the bottom tray so that all secondary electronic components can be connected to primary electronic components mounted in the external body. The computing unit has a high modularity and a top secondary electronic component can be removed without removing the external body from an HPC cabinet.

Preferably, at least one of the top secondary electronic components is an expansion card, extending longitudinally in the computing unit from the front to the rear, and another one of the top secondary electronic components is an interface card connected to the top connector. The expansion card is connected to the interface card thanks to a lateral connection. Such an expansion card can use the entire length of the top tray which is advantageous for a FHFL format.

Preferably, the top tray comprises a fastening system, independent from the lateral connection, coupling mechanically the expansion card to the top tray. Such a fastening allows guiding the expansion card to protect the lateral connection.

According to an aspect of the invention, the fastening system is configured to guide the expansion card relatively to the interface card along a guiding path formed in the top tray. Preferably, the guiding path comprises at least a lateral slot. The expansion card is guided mechanically without increasing the size of the computing unit or the top tray.

According to an aspect of the invention, the fastening system comprises at least one fastening member for locking the expansion card with the top tray, preferably two. Preferably, at least one fastening member is a thumbscrew. Such a fastening member doesn't require a user to use tools for removing the expansion card. Preferably, the fastening portion comprises a foot portion which is guided within the lateral slot.

According to an aspect of the invention, the fastening system comprises at least a supporting frame comprising a horizontal portion, configured to cooperate with the top tray, and a vertical portion, configured to cooperate with the expansion card. Preferably, the fastening system comprises locking members which are locking the vertical portion to the expansion card.

According to an aspect of the invention, the expansion card has a Full-Length Full Height format. Preferably, the expansion card is connected to the interface card thanks to a lateral PCle connection. The computing unit comprises at least two expansion cards.

The invention relates also to a method for removing an expansion card from the top tray of the internal body of a computing unit, presented before, the expansion card being connected to the interface card thanks to a lateral connection, the method comprising:.

A better understanding of embodiments of the present disclosure (including alternatives and/or variations thereof) may be obtained with reference to the detailed description of the embodiments along with the following drawings, in which:.

Reference will now be made in detail to specific embodiments or features, examples of which are illustrated in the accompanying drawings. Wherever possible, corresponding or similar reference numbers will be used throughout the drawings to refer to the same or corresponding parts. Moreover, references to various elements described herein are made collectively or individually when there may be more than one element of the same type. However, such references are merely exemplary in nature. It may be noted that any reference to elements in the singular may also be construed to relate to the plural and vice-versa without limiting the scope of the disclosure to the exact number or type of such elements unless set forth explicitly in the appended claims.

A datacenter comprises several high-performance computing cabinets, called HPC cabinets or "clusters", arranged in rows within the datacenter and configured to house computing units, such as servers, switches and routers, to organize, process and store data. A HPC cabinet is configured to accommodate multiple server units, switches, cords and cables, rails, cable management bars, routers, path panels, and blanking panels.

High performance computing has gained importance in recent years by several industries which are trending towards increasing sizes or combinations of two or more servers to achieve faster processing performance for a large number of processing operations. Solutions known to address such requirement of the industries include Ultra Path Interconnect (UPI) technology which provides a scalable multiprocessor system, for example, by linking motherboards of two or more computing units together.

As illustrated in <FIG>, a HPC cabinet <NUM> comprises two vertical side walls <NUM>, delimiting a central cavity with a front opening, so as to define vertically stacked sockets S having a standard height (U). Several computing units <NUM> are housed in the HPC cabinet <NUM> and mounted onto the two vertical side walls <NUM>. In this example, the height of each computing device <NUM> is 2U but could be different.

Each vertical side wall <NUM> comprises a front portion which is configured to cooperate with an abutment wall of a computing unit <NUM>. In this example, the front portion of each side wall <NUM> comprises threaded openings <NUM>. Such an HPC cabinet <NUM> is known from the prior art and won't be further detailed.

A computing unit <NUM> according to the invention will be now presented. In this embodiment, as represented in <FIG>, <FIG>, the computing unit <NUM> comprises an internal body <NUM> mounted within an external body <NUM>, the internal body <NUM> being releasably coupled to the external body <NUM> in order to allow extraction of the internal body <NUM> when the external body <NUM> is fixedly secured to the HPC cabinet <NUM>. As illustrated in <FIG>, the computing unit <NUM> is presented in the (X, Y, Z) referential in which the X axis extends longitudinally from the front to the rear, the Y axis extends laterally from the right to the left and the Z axis extends vertically from the bottom to the top.

According to the invention, as represented in <FIG>, the external body <NUM> comprise lateral walls <NUM>, a bottom wall <NUM> (see <FIG>) and a top wall <NUM> defining together a housing (the top wall <NUM> is not represented in the <FIG>). As represented in <FIG>, the external body <NUM> defines a front housing H1 where the internal body <NUM> can be mounted and a back housing H2 where primary electronic components C1 are located, for example, at least one mother board and components secured to the mother board such as processors, Dual In-Line Memory Module (DIMM), etc. The internal body <NUM> is configured to be releasably coupled to the primary electronic components C1 of the back housing H2. The external body <NUM> comprises at least a first connector K1 connected to the primary electronic components C1. The first connector K1 is located at the interface between the first housing H1 and the second housing H2.

As represented in <FIG>, each lateral wall <NUM> of the external body <NUM> comprises an abutment wall <NUM> configured to be connected to the HPC cabinet <NUM>, for example, by screws. Each abutment wall <NUM> is located in a front end of the external body <NUM>. In this embodiment, as represented in <FIG>, the computing unit <NUM> comprises, at each side of the internal body <NUM>, a front lever <NUM> pivotally coupled to the internal body <NUM> for releasably coupling the internal body <NUM> with the external body <NUM>. The coupling means could be different.

The internal body <NUM> comprises at least a second connector K2 connected to secondary electronic components of the internal body <NUM>, the second connector K2 being configured to cooperate with the first connector K1 of the external body <NUM> when the internal body <NUM> is coupled with the external body <NUM> (See <FIG>). The second connector K2 is located at the rear end of the internal body <NUM>, preferably, at the rear end of the bottom tray <NUM> as it will be presented later.

As represented in <FIG>, the internal body <NUM> comprises a bottom tray <NUM> and a top tray <NUM> which is releasably coupled with the bottom tray <NUM>.

According to <FIG>, the bottom tray <NUM> comprises several bottom secondary components A0-A3. In this example, the bottom secondary electronic components are in the form of fans A0, processor cooler A1, Dual In-Line Memory Module (DIMM) A2, etc. The fans A0 are located at the front so that air can flow from the front to the rear in the computing unit <NUM>. In this example, the internal body <NUM> comprises a front housing <NUM> in order to receive an interconnecting module (not represented) configured to interconnect several computing units together. The bottom tray <NUM> comprises a bottom wall <NUM> for supporting the secondary electronic components A0-A3 and side walls <NUM>. As it will be presented in details later, the bottom tray <NUM> comprises at least a bottom connector K4 connected to the bottom secondary electronic components A0-A3. In this example, the bottom connector K4 extends vertically to the top.

The top tray <NUM> comprises ventilation ducts <NUM> so that fresh air, coming from the front fans A0, can be guided to the rear of the computing unit <NUM> (to the primary components C1).

As illustrated in <FIG>, the top tray <NUM> comprises a supporting wall <NUM>, having a U-shape, and two lateral holding walls <NUM>, extending in a (X,Y) plane, configured to vertically abut with the side walls <NUM> of the internal body <NUM>/bottom tray <NUM>. The top tray <NUM> covers almost completely the bottom tray <NUM>. The top tray <NUM> comprises two ventilation ducts <NUM> configured to guide the air flow from the fans A0 to the rear of the computing unit <NUM>.

According to the invention, as illustrated in <FIG>, the top tray <NUM> comprises top secondary electronic components. As represented in <FIG>, the top tray <NUM> comprises two expansions cards <NUM> having, preferably, a Full-Length Full Height format (FLFH format). In this example, each expansion card <NUM> comprises a GPU (Graphical Processing Unit). The top tray <NUM> comprises also several interface cards, particularly, one connection card <NUM> for each expansion card <NUM> and a central card <NUM> for connecting the connection cards <NUM>. The expansions cards <NUM> and the interface cards <NUM>, <NUM> are top secondary electronic components.

The top tray <NUM> comprises at least a top connector K5 connected to the top secondary electronic components <NUM>, <NUM>, <NUM>, the top connector K5 being configured to cooperate with the bottom connector K4 of the bottom tray <NUM> when the top tray <NUM> is coupled with the bottom tray <NUM>. In this example, the top connector K5 belongs to the central card <NUM> but it could be different.

The top tray <NUM> is releasably coupled with the bottom tray <NUM> so that a customer can replace directly the expansion cards <NUM> without having to remove entirely the internal body <NUM> from the HPC cabinet. In this example, the top connector K5 is connected to the bottom connector K4 by a flexible cable (not represented) but the top connector K5 could also be fitted directly to the bottom connector K4.

Thanks to the invention, the top tray <NUM> is used to guide the air flow but also to mount large components which require heavy cooling, such as GPU.

As represented in <FIG>, each expansion card <NUM> extends longitudinally along the X axis and comprises a lateral connector <NUM>. Each connection card <NUM> comprises a lateral socket <NUM>, preferably a PCle connector, configured to cooperate with the lateral connector <NUM>. In other words, when connecting/disconnecting an expansion card <NUM>, said expansion card <NUM> has to be moved along the Y axis relatively to the connection card <NUM> in order to avoid damaging the pins of the lateral connector <NUM>.

The top tray <NUM> comprises a fastening system <NUM>, independent from the lateral socket <NUM>, coupling mechanically the expansion card <NUM> to the top tray <NUM>. The fastening system <NUM> is configured to guide the expansion card <NUM> during connection/disconnection along a guiding path formed in the top tray <NUM>. To this end, as illustrated in <FIG>, the guiding path comprises a lateral slot G which extends along the Y axis. The length of the lateral slot G is comprised preferably between <NUM> and <NUM> to allow disconnection.

According to <FIG>, the fastening system <NUM> comprises a supporting frame <NUM> fixed to the expansion card <NUM> and at least one fastening member <NUM>, mounted onto the supporting frame <NUM>, for locking the expansion card <NUM> with the top tray <NUM>, preferably two. In this example, as represented in <FIG>, the supporting frame <NUM> is L-shaped and comprises a horizontal portion <NUM>, configured to cooperate with the top tray <NUM>, and a vertical portion 70v, configured to cooperate with the expansion card <NUM>. The fastening system <NUM> comprises locking members <NUM>, preferably screws of thumbscrews, which are locking the vertical portion 70v to the expansion card <NUM>.

In this example, each fastening member <NUM> is a thumbscrew so that a customer can use the fastening system <NUM> without any tool. Each fastening member <NUM> comprises a head portion 71a which can be rotated by hand by a customer without any tool and a foot portion 71b which can cooperate with the lateral slot G. Depending on the orientation of the fastening members <NUM>, the foot portion 71b can be tighten to the top tray <NUM> or free to move in the lateral slot G. Preferably, a portion of the lateral slot G is wider so that the expansion card <NUM> can be removed vertically when the expansion card <NUM> has been sufficiently guided away from the lateral socket <NUM> of the connection card <NUM>.

It will now be described a method for removing an expansion card <NUM> connected to an interface card, here a connection card <NUM>, on the top tray <NUM>. In the initial position, the internal body <NUM> is located in the housing H1 of the external body <NUM> (see <FIG>). As illustrated in <FIG>, the user then pulls the internal body <NUM> out from the external body <NUM>. The user then lifts the top tray <NUM> from the bottom tray <NUM> so that the top tray <NUM> can be easily accessible. The top connector K5 of the top tray <NUM> is disconnected manually or automatically from the bottom connector K4 of the bottom tray <NUM>.

If the user wants to remove an expansion card <NUM> mounted in the top tray <NUM>, the user firstly unlocks (E1) (<FIG>) the expansion card <NUM> from the top tray <NUM> by manually rotating the head portion 71a of the fastening members <NUM> so that the expansion card <NUM> is freed from the supporting wall <NUM>.

Then, the expansion card <NUM> can be laterally moved (E2) to the left by guiding the foot portion 71b of the fastening members <NUM> within the lateral slot G so that the expansion card connector <NUM> can disconnect properly from the lateral socket <NUM> of the connection card <NUM>. The lateral sliding allows to avoid damaging the pins of the lateral connector <NUM>. Then, the expansion card can be removed (E3) vertically without any damage (<FIG>). The steps are represented schematically in <FIG>.

If needed, the supporting frame <NUM> is removed from the old expansion card by acting on the locking members <NUM> and mounted onto a new expansion card. Advantageously, the fastening systems <NUM> can also guide the expansion card <NUM> during the connection.

All terminologies used herein are for purposes of describing embodiments and examples and should not be construed as limiting the invention. Furthermore, to the extent that the terms "including," "includes," "having," "has," "with," or variants thereof, are used in either the detailed description and/or the claims, such terms are intended to be inclusive in a manner similar to the term "comprising.

Claim 1:
A computing unit (<NUM>) configured to be mounted in a High-Performance Computing cabinet (<NUM>), thereafter HPC cabinet (<NUM>), defining a plurality of vertically stacked sockets (S), the computing unit (<NUM>) comprising:
• an external body (<NUM>) configured to engage with at least one of the sockets (S), the external body (<NUM>) comprising at least a bottom wall (<NUM>) and two lateral walls (<NUM>) defining a housing comprising a front housing (H1) opened from the front and a back housing (H2) where primary electronic components (C1) are located, each lateral side (<NUM>) comprising an abutment wall (<NUM>) configured to be secured directly to the HPC cabinet (<NUM>), the external body (<NUM>) comprising at least a first connector (K1) connected to the primary electronic components (C1),
• an internal body (<NUM>), comprising secondary electronic components (A0-A3, <NUM>, <NUM>, <NUM>), the internal body (<NUM>) being releasably coupled with the external body (<NUM>) when mounted on the front housing (H1) in order to allow extraction of the internal body (<NUM>) when the external body (<NUM>) is secured fixedly to the HPC cabinet (<NUM>), the internal body (<NUM>) comprising at least a second connector (K2) connected to the secondary electronic components (A0-A3, <NUM>, <NUM>, <NUM>), the second connector (K2) being configured to cooperate with the first connector (K1) when the internal body (<NUM>) is coupled with the external body (<NUM>),
• the internal body (<NUM>) comprising:
i. a bottom tray (<NUM>), comprising bottom secondary electronic components (A0-A3) and at least a bottom connector (K4) connected to the bottom secondary electronic components (A0-A3), the bottom tray (<NUM>) comprising front fans (A0),
ii. a top tray (<NUM>) being releasably coupled with the bottom tray (<NUM>), the top tray (<NUM>) comprising top secondary electronic components (<NUM>, <NUM>, <NUM>) and at least a top connector (K5) connected to the top secondary electronic components (<NUM>, <NUM>, <NUM>), the top connector (K5) being configured to cooperate with the bottom connector (K4) when the top tray (<NUM>) is coupled with the bottom tray (<NUM>), the top tray (<NUM>) comprising two ventilation ducts (<NUM>) configured to guide the air flow from the front fans (A0) to the back housing (H2) of the computing unit (<NUM>).