Patent Description:
Data center utilizing air thermal separation technique coined as a cold/hot aisle or server enclosure is well known. <CIT> premises on a type of server/equipment rack heat removal by placing the back of each of the racks adjacent to one another, thereby forming a relatively narrow space between each of the back of the racks. The hot air is then channeled to a containment where cooling of the hot air is carried out. However, there are shortcomings on such teachings, i.e., due to the racks are back-to-back and in a relatively narrow manner, the server rack fan may have to work extra to push the hot air upward as opposed to the present invention whereby the heat removal cabinet is adapted and configured adjacent to the heat source. <CIT> discloses a frame configured to be mounted to a server rack, the frame further comprising a heat exchanger.

Accordingly, a chamber is provided to allow heated air generated from the server racks in a cluster to be mixed, channelled, and diffused prior to a heat removal cabinet.

Accordingly, the chamber effectively and efficiently conveys heated air to the corresponding heat removal cabinet so that cooling capacity of the cabinet can be maximized.

Accordingly, the chamber provides a plurality partitions enabling heat removal cabinets to be fitted; unused or empty partitions can be sealed by inner and outer enclosures. Further, to provide redundancy in cooling capacity, the chamber is configured so that additional heat removal cabinets can be fitted.

Accordingly, angle of diffusion can be configured manually or automatically to allow a predetermined heated air to be cooled by the heat removal cabinets.

Additional objects of the invention will become apparent with an understanding of the following detailed description of the invention or upon employment of the invention in actual practice.

The invention is defined by the independent claim. Further aspects of the invention are outlined in the dependent claims.

Other aspect of the present invention and their advantages will be discerned after studying the Detailed Description in conjunction with the accompanying drawings in which:.

However, it will be understood by the person having ordinary skill in the art that the invention may be practised without these specific details. In other instances, well known methods, procedures and/or components have not been described in detail so as not to obscure the invention.

The invention is not limited in its application to the construction and arrangement of equipment, instrument, or ancillary components set forth in the following description or illustrated in the drawings. Although a preferred embodiment and best mode are described, the claims are not limited as such, rather scope of the claims are defined and structured to include the preferred embodiment and best mode. The terminology used such as "including", "comprising", "containing", "having", or other variations should not regarded as limiting; it is meant to encompass the items listed and equivalents thereof as well as additional items by a skilled artisan.

The invention will be more clearly understood from the following description of the embodiments thereof, given by way of example only with reference to the accompanying drawings, which are not drawn to scale.

Referring to <FIG>, there is shown a perspective view of a preferred embodiment server cluster frame (<NUM>) flanked by a pair of hot air staging chambers or mixing chambers (<NUM>). The server cluster frame (<NUM>) generally comprising an arrangement of vertical frames (<NUM>), width frames (<NUM>), and depth frames (<NUM>) so that a server rack can be coupled on. A web surface (<NUM>) can be mounted on the depth frames (<NUM>) serves as a walk way corridor. Here shown this embodiment of the mixing chamber (<NUM>) which is contiguous with the server cluster frame (<NUM>), generally comprising top surface (<NUM>) preferably impermeable, extends from the topmost width frame; depth frame (<NUM>) extends from low region of the vertical frame (<NUM>) forming a depth perspective, a width frame (<NUM>) then coupled with the depth frames (<NUM>) forming a width perspective or foundation. It is also envisaged that another embodiment of the chamber (<NUM>) can be removably attached to the server cluster frame (<NUM>).

Referring now to <FIG>, there is shown a view of a preferred embodiment server cluster frame comprising a hot air staging chamber or mixing chamber with dividers or partition assemblies (<NUM>) installed. In <FIG> shows another view of a preferred embodiment server cluster frame comprising a hot air staging chamber or mixing chamber with dividers or partition assemblies (<NUM>) installed. A server rack (not shown) can be coupled on each of the partition. A bottom surface (<NUM>) disposed on the foundation of the chamber formed between the depth frame (hidden) and width frame (<NUM>), the bottom surface may employ an impermeable material thereby limiting air leakages therein. Also it is envisaged that lateral top and side surfaces (<NUM>, <NUM>) employ impermeable material. Hence it is defined that a first major surface comprising a plurality of partition assembly (<NUM>) can be configured to width and height of communicating server racks (<NUM>) or outer enclosures (<NUM>); and a second major surface comprising a plurality of partition assembly (<NUM>) can be configured to width and height of communicating heat removal cabinet (<NUM>) or inner enclosure (<NUM>). The partition assembly (<NUM>) has web structure (<NUM>) thereon, enabling heated air therethrough so that volume of the heated air is mixed homogenously and temperature of the heated air in the chamber approaches equilibrium. Further, the partition assembly (<NUM>) can be coupled with an air diffusing means comprising at least one diffuser (<NUM>) mounted substantially vertical between guide plates (<NUM>).

Referring to <FIG>, there is shown an exemplary of an arrangement of uniform sized server racks (<NUM>) disposed on a rack pallet (<NUM>) may comprising rollers allowing mobility, the racks (<NUM>) can be moved and coupled to each individual partition of the chamber (<NUM>) which coupled to the server cluster frame (<NUM>). Partitions that are not in used are sealed with an outer (<NUM>) and inner enclosure (<NUM>), also to keep the mixing chamber (<NUM>) sealed. Between the two chambers (<NUM>) or interior of the server cluster frame (<NUM>) is the walk way or corridor can be regarded as "mixed" aisle. Inside the "mixed" aisle, the heated air which ejected from the server racks is cooled down by heat removal cabinet, the air temperature inside the "mixed" aisle can be warmer or about the ambient air temperature. The exterior part of the chambers (<NUM>) can be regarded as "cold" aisle whereby cold air can be defined as having ambient air temperature, or cold air can be supplied by computer room air conditioning unit (CRAC) or the cold air can be supplied underneath a raise floor (<NUM>) which served as a cold air plenum, then the cold air travels through a perforated/ grilled floor tile (<NUM>) to the server racks (<NUM>). Referring now to <FIG>, there is shown another view of <FIG> showing the installation of the inner enclosure (<NUM>). Referring now to <FIG>, there is shown another embodiment of a small server rack (<NUM>), outer enclosure (<NUM>) can be configured to seal any exposed area of the chamber (<NUM>).

In <FIG> shows an exemplary embodiment system (<NUM>) for heat removal from server racks. Here the arrangement of server racks are removed, exposing a heat removal cabinet (<NUM>) with cabinet heat side receiving heated air generated from the server racks, this embodiment of heat removal cabinet (<NUM>) has water/ air heat exchanger therein which coupled to a chilled water supply (<NUM>) and chilled water return (<NUM>). Although in this embodiment, the heat removal cabinet (<NUM>) relies on heat transfer between heated air and chilled water; in following part of the description, a preferred embodiment of heat removal cabinet (<NUM>) is further explained. Partitions not coupled with server racks are covered or sealed by outer enclosure (<NUM>) and inner enclosure (<NUM>). In <FIG> shows another view of <FIG> of the heat removal cabinets (<NUM>) with cabinet fan-side. In this embodiment of heat removal cabinet (<NUM>) receives chilled water/liquid supply (<NUM>) demarcated by white arrowhead, then returns warm water to chilled water return (<NUM>) demarcated by black arrowhead. The system (<NUM>) for heat removal from server racks, comprising of a mixing chamber (<NUM>) of a substantially rectangular frame, defined by a first major surface configured to attach or removably attach on a server cluster frame (<NUM>), wherein the first major surface receiving heat generated from the server racks, a second major surface configured to attach or removably attach on at least one heat removal cabinet (<NUM>), wherein the second major surface expelling the heat to the heat removal cabinets (<NUM>); impermeable top (<NUM>), bottom (<NUM>) and lateral surfaces (<NUM>) disposed adjacent to the major surfaces forming an enclosure of the chamber.

Referring to <FIG>, there is shown a preferred embodiment heated air mixing chamber (<NUM>) coupled with impermeable top (<NUM>), lateral (<NUM>), and bottom surfaces (<NUM>), at least one partition assembly (<NUM>), and at least one diffuser (<NUM>). In <FIG> shows an enlarged view of bottom portion of the preferred embodiment heated air mixing chamber (<NUM>).

In <FIG>, there is shown an enlarged view of top portion of the preferred embodiment heated air mixing chamber (<NUM>). Then in <FIG>, there is shown an enlarged view of the bottom portion of the preferred embodiment of actuator (<NUM>) to configure angle of diffusion (α,β) of the diffuser (<NUM>). The partition assembly (<NUM>) has web structure (<NUM>) thereon, enabling heated air therethrough so that volume of the heated air is mixed homogenously and temperature of the heated air in the chamber approaches equilibrium. The partition assembly (<NUM>) coupled with an air diffusing means comprising at least one diffuser (<NUM>) mounted substantially vertical between guide plates (<NUM>). A pin (<NUM>) affixed each end of the diffuser on the guide plates, allowing the diffuser to be pivotable longitudinally. To enable effectively and efficiently diffuse the heated air, the diffuser (<NUM>) comprising web structure (<NUM>) can configure to manually or automatically pivotable to provide a diffusion angle (α,β) with respect to the plane of the major surfaces. Further, the diffuser is operatively connected to an actuator (<NUM>) comprising actuation rod (<NUM>) or linkage, whereby upon an actuation or retraction of the rod or linkage to adjust the diffusion angle with respect to the plane of the major surfaces. Alternatively, the actuator (<NUM>) is operatively connected to a computer or controller (<NUM>) wherein the computer comprising executable programs receiving telemetry data from measuring instrument of working fluids, such as but not limited to, temperature, energy, pressure, mass flow rate, thereby instructing the actuators (<NUM>) to configure the diffusion angles (α,β), respectively. Fluids are defined as liquid, gas, or a combination thereof; thus the working fluids in this regard are air, chilled water, and refrigerant.

In <FIG> shows a perspective view of the present invention, a preferred embodiment system (<NUM>) of heat removal for server racks, with the outer and inner enclosures omitted exposing the heat removal cabinets (<NUM>). As explained in <FIG> and <FIG>, the heat removal cabinet (<NUM>) may receive chilled water (<NUM>) to cool the heated air. However, water has less efficient heat transfer capability compare to refrigerants, such as chloroflurocarbons (CFC), hydrochlorofluorocarbons (HCFC), hydrofluorocarbons (HFC), and hydrocarbon (HC). Due to adverse effect of chlorine-based refrigerants which can deplete ozone layer and cause global warming, these refrigerants are no longer manufactured and are prohibited to use. Therefore, it is preferred that refrigerant with low ozone depleting potential and global warming potential is used. Here, the heat removal cabinets (<NUM>) acts as a refrigerant evaporator, a refrigerant/chilled water heat exchanger (<NUM>) acts as a refrigerant condenser, comprising two inlets and two outlets: receives chilled water supply (<NUM>); receives refrigerant vapor (<NUM>) from the heat removal cabinets (<NUM>), a heat transfer is taking place so that the refrigerant vapor is cooled or chilled until a refrigerant phase change to liquid then discharges the refrigerant liquid (<NUM>) back to the cabinets (<NUM>), and discharges water back to chilled water return (<NUM>). Accordingly in this embodiment, the refrigerant/chilled water heat exchanger (<NUM>) is installed relatively higher than the heat removal cabinets (<NUM>), as the refrigerant phase changes from vapor to liquid in the heat exchanger (<NUM>), the refrigerant liquid (<NUM>) is relatively heavy, can flow in a relatively small diameter pipe (demarcated by black arrowhead) to the cabinets by gravitational force, as the refrigerant liquid vaporizes (or phase change), the refrigerant's pressure increases. While the refrigerant vapor (<NUM>) is relatively light and buoyant, can flow in a relatively large diameter pipe (demarcated by white arrowhead).

Accordingly in this embodiment explains passive or "free" cooling, the condensation and vaporization of the refrigerant in the heat exchanger (<NUM>) do not require additional work-done or input power from refrigerant compressor or pump. Though it is envisaged that forced cooling which require refrigerant compressor or pump, expansion valve, hot-gas bypass and other ancillaries can be adapted or configured, if required, to suit for refrigerant of different thermodynamic properties. In <FIG> shows a preferred embodiment heat removal cabinets (<NUM>) heat receiving side which abuts the mixing chamber, the heat receiving side comprising a web structure (<NUM>) or perforated door to allow heated air therethrough. The cabinet (<NUM>) may contain at least one heat exchanger (<NUM>) therein, the heat exchangers (<NUM>) can be coupled either (i) serially or (ii) in parallel shown in <FIG>. It is envisaged that valves (<NUM>) such as flow valves, check valves, or the like, can be fitted in the parallel coupled heat exchangers so that not in used heat exchangers can be shut off, or prevent back flow of refrigerant vapor. As the refrigerant liquid (<NUM>) demarcated by a black arrowhead, enters heat exchanger inlet (<NUM>), heat transfer is taking place inside the heat exchanger, the refrigerant liquid phase changes to refrigerant vapor. Due to the buoyancy force in the refrigerant vapor, it exits through a heat exchanger outlet (<NUM>). A valve (<NUM>) is provided at the outlet (<NUM>) but prior to the chilled water return (<NUM>), mainly serves as a refrigerant flow control or can be shut off any heat removal cabinet (<NUM>) not in use. In <FIG> shows the preferred embodiment heat removal cabinets fan-side. The heat removal cabinet (<NUM>) comprising at least one heat exchanger (<NUM>) therein, receiving a cooling fluid such as chilled water, refrigerant, air, or the like. The cooling fluid is configured at a volume flow rate, pressure, temperature, or a combination thereof, to cool the heated air by control valves, mass flow meter, energy meter, BTU meter, thermometer, or the like. The heat exchanger (<NUM>) is selected from one or more of the following types: fin, shell and tube, brazed plate, or the like, can has/have cross flow, counter flow, counter-current, or the like. The heat removal cabinet (<NUM>) combined with a plurality of fans (<NUM>) provides a substantial differential static pressure between the cabinet and ambient, driving the air flow across the heat exchanger between the cabinet and chamber.

Referring to <FIG>, there is shown a schematic diagram of a preferred embodiment heat exchanger (<NUM>) interconnected by a chilled water/refrigerant heat exchange systems represented by one side of closed-loop chilled water system (<NUM>) and other side of closed-loop refrigerant system (<NUM>). As explained, the heat exchanger (<NUM>) serves as a refrigerant condenser and the heat exchanger (<NUM>) serves as a refrigerant evaporator. To enable sufficient amount of cooling capacity provided to the heat exchangers (<NUM>, <NUM>), sensors are mounted on both systems (<NUM>, <NUM>), such as but not limited to, insertion type or non-invasive (ultrasonic) type of thermometers, thermocouples, thermistors, or the like to provide telemetry data of water/refrigerant supply/return temperatures (<NUM>, <NUM>, <NUM>, <NUM>), hot or cold aisle temperature (<NUM>), heat removal cabinet water/refrigerant temperature (<NUM>); mass flow rate meters, air flow velocities anemometer, air and liquid pressure gauges, BTU energy meter, or the like. These telemetry data are collected by the controller or computer (<NUM>) comprising executable programs and predetermined set values, so that it can configure a return chilled water valve (<NUM>) to fully open, partially open, or fully close.

Referring to <FIG>, there is shown an exemplary data center arrangement comprising zones of server clusters and backup cooling unit for a data center. It has <NUM> zones, each zone has <NUM> clusters and <NUM> backup cooling unit. Each backup cooling unit has <NUM> air supply and <NUM> air return. Though this exemplary arrangement is for data center in a facility or building, it is envisaged that the present invention can be configured for a containerized data center.

<FIG> shows an exemplary of a server cluster (demarcated by dotted line in <FIG> and rotated by <NUM> degrees) running at <NUM>% capacity and heat removal cabinets also running at <NUM>% cooling capacity. As shown is one example, it has <NUM> rows of server racks. Each row has <NUM> units of server racks, <NUM> units of heat removal cabinets, of which <NUM> units are connected to <NUM> heat exchanger in an alternative fashion. There is a region, called staging chamber, whereby hot air is mixed homogenously before entering the heat removal cabinets. After heat removal module, cool air exits into a region called Kool-Corridor.

Each zone has <NUM> clusters and requires <NUM> backup cooling unit. As such, in a data center hall, the number of backup cooling unit required can be scaled according to the following: <MAT> For example:
In a data center of <NUM> clusters of racks, the number of backup cooling units required are <NUM>/<NUM> = 4units.

The heat removal cabinets (<NUM>) of same row are arranged by alternating a number of the cabinets (N) and a vacant space. Furthermore, the vacant space enabling a redundancy higher than the number of cabinets, providing redundancy cooling capacity or backup cooling capacity.

For KoolLogix solution, it has two possibilities of cooling breakdown: heat removal module breakdown and heat exchanger breakdown. Backup cooling unit is of necessary when heat exchanger is breakdown. For cooling redundancy solution, it can be evaluated from energy balance perspective and can be referred to the following: <MAT>.

Claim 1:
A system (<NUM>) for heat removal from server racks (<NUM>), comprising:
a mixing chamber (<NUM>) of a substantially rectangular frame, defined by:
a first major surface configured to receive heat generated from the server racks (<NUM>),
a second major surface configured to expel the heat to at least one heat removal cabinet (<NUM>);
impermeable top (<NUM>), bottom (<NUM>) and lateral surfaces (<NUM>) disposed adjacent to the major surfaces, thus forming an enclosure of the mixing chamber (<NUM>);
wherein:
the mixing chamber (<NUM>) comprises at least one divider (<NUM>) configured to divide the mixing chamber (<NUM>) into a plurality of partitions,
wherein each partition of the plurality of partitions is configured to couple along the width and height of a server rack (<NUM>) at the first major surface (<NUM>); and
wherein each partition of the plurality of partitions is configured to couple along the width and height of a heat removal cabinet (<NUM>) at the second major surface; and
wherein the at least one divider (<NUM>) has a web structure (<NUM>) for enabling heated air therethrough so that a volume of the heated air is mixed homogenously and a temperature of the heated air in the mixing chamber (<NUM>) approaches equilibrium.