US20060023422A1

US20060023422A1 - Modular electronic enclosure with cooling design

Info

Publication number: US20060023422A1
Application number: US11/243,612
Authority: US
Inventors: Kent Shum; Randall Diaz; Robert Tong; Perry Hayden; Ming Leong
Original assignee: Individual
Current assignee: Individual
Priority date: 2004-01-28
Filing date: 2005-10-05
Publication date: 2006-02-02
Also published as: US20050162831A1; US6980435B2

Abstract

An embodiment of a modular electronic enclosure is provided as including a chassis having a first portion defining a first compartment, and a second portion defining a second compartment. First and second replaceable units are replaceably received within the first and second compartments, respectively. The modular electronic enclosure also has a fan unit that is replaceably received within a compartment defined by the first portion or the second portion. The fan unit is configured to pull in cooling air through the first portion and exhaust pressurized cooling air through the second portion. A method of cooling a modular electronic enclosure defining first and second compartments is also provided.

Description

BACKGROUND

Earlier of electronic enclosures, such as those used in servers, were stacked one on top of the other in standard Electronic Industry Association (EIA) racks. These earlier enclosures carried various electronic components, such as a power supply, a logic board or “motherboard,” input/output ports, and a fan unit, but these components were in cumbersome arrangements. For instance, to service the interior components, either a snap-on front plate or a conventionally hinged front door first had to be opened, or the entire enclosure taken from the rack and a top cover removed. Often the fan had to be removed before electronic components could even be accessed. This accessing operation was particularly difficult for servicing personnel, since if the unit was deactivated, replacement had to be accomplished within a short time span (e.g., ten minutes) so other components would not lose stored information. Also, the number and size of components housed within these earlier enclosures was often limited by the cooling capability of the enclosure. In some earlier front access enclosures, the ability to control fan airflow when changing components was limited by their air dam designs, which function to limit fan air in-take when a component is removed. These earlier air dams were either a hinged saloon door style, or a horizontally hinged door relying on gravity for closure, both of which inherently leak-in large quantities of air.

SUMMARY

An embodiment of a modular electronic enclosure is provided as including a chassis having a first portion defining a first compartment, and a second portion defining a second compartment. First and second replaceable units are replaceably received within the first and second compartments, respectively. The modular electronic enclosure also has a fan unit that is replaceably received within a compartment defined by the first portion or the second portion. The fan unit is configured to pull in cooling air through the first portion and exhaust pressurized cooling air through the second portion.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention can be further understood by reference to the following description and attached drawings that illustrate the embodiment(s). Other features and advantages will be apparent from the following detailed description of the embodiment(s), taken in conjunction with the accompanying drawings, which illustrate, by way of example, the principles of the invention.
FIG. 1 is a partially fragmented, front elevational view showing one embodiment of a modular electronic enclosure of the present invention mounted in an EIA rack for use, actually showing two enclosures, one with a front faceplate bezel closed, and the other with the bezel open;
FIG. 2A-2E show the bezel latching mechanism of FIG. 1, with:
FIG. 2A being an enlarged, exploded view,
FIG. 2B being an enlarged perspective view shown before attaching the bezel,
FIG. 2C being an enlarged detailed perspective view during attachment,
FIG. 2D being an enlarged detailed perspective view shown after attachment, and
FIG. 2E being an enlarged cross sectional view taken along lines 2E-2E of FIG. 2A;
FIG. 3 is a perspective view of a chassis of the enclosure of FIG. 1, with various replaceable units (CRU's) of electronics removed;
FIG. 4 is a perspective view of a logic board or “motherboard” of the enclosure FIG. 1, shown partially removed from the chassis;
FIG. 5 is a perspective view of a power unit of the enclosure FIG. 1, shown partially removed from the chassis;
FIG. 6 is a perspective view of a fan unit of the enclosure FIG. 1, shown partially removed from the chassis;
FIG. 7 is a perspective view of an input output unit of the enclosure FIG. 1, shown partially removed from the chassis;
FIG. 8 is a top plan view showing a diagram of airflow through the enclosure of the FIG. 1; and
FIG. 9 is a side elevational view showing a diagram of airflow through the enclosure of the FIG. 1.

DETAILED DESCRIPTION OF THE EMBODIMENTS

In the following description of the invention, reference is made to the accompanying drawings, which form a part hereof, and in which is shown by way of illustration a specific example in which the invention may be practiced. It is to be understood that other embodiments may be utilized and structural changes may be made without departing from the scope of the present invention.
I. General Overview:
FIG. 1 shows one embodiment of a modular electronic enclosure 100 mounted to a standard EIA rack for convenience, although other mounting systems may be employed. The enclosure 100 includes a front faceplate or bezel 104, which is shown in a closed position. Also shown in FIG. 1 is a modular electronic enclosure 100 a, identical to enclosure 100 except that the bezel 104 is shown in an open position. Note the use herein of the an alpha designator (a) indicates different placement or position of a like-numbered component without the prime designator, unless otherwise noted. Bezel 104 includes a frame 105 and a series of air inlet apertures or inlet ports 106. The bezel 104 may also include provisions for viewing a display 108, which may provide identifying, status, or other information regarding components within the enclosure 100.
The bezel 104 may be opened with a bezel latching mechanism 110, described in further detail below, when a latch, such as spring-loaded latch 112 is activated. When closed, the latch 112 engages a latch post 114 projecting from a chassis 115 of enclosure 100. Housed within chassis 115 are a variety of electrical components, in this embodiment, customer replaceable units (CRU's), such as a logic board or motherboard 116, a pair of power units 118, 118 a, and a pair of fan units 120, 120 a. The motherboard 116 may be removably secured within chassis 115 by a pair of latches 122 supported by a frame 124 of motherboard 116. The frame 124 may also support various input devices for the motherboard 116, such as a pair of scrolling (up/down) buttons 125 which may be used to show and/or select different information on display 108. The frame 124 defines a series of air inlet apertures or ports 126, here shown arranged around the latches 122, although other locations in the front portion of frame 124 may be more suitable in other implementations.
In a similar fashion, each of the power units 118, 118 a may be held in place by a latch 128 supported by a frame 130 of each power unit. Each power unit frame 130 defines a series of air inlet apertures or ports 132. Each fan unit 120, 120 a may be held in place by a latch 134 supported by a frame 136 of each fan unit. Each fan unit frame 136 defines a series of air inlet apertures or ports 138. Location of the inlet ports 132, 138 are shown by way of example only, and may be placed in other arrangements in other implementations.
This completes the overview discussion of the front loading CRU's housed within the modular electronic enclosure 100. Before moving on to other portions of the enclosure 100, one embodiment of a bezel latch mechanism 110 will be discussed.
II. Bezel Latch Mechanism:
FIGS. 2A-2E show one embodiment of a bezel latch mechanism 110 used in enclosure 100 to attach the bezel 104 to the enclosure chassis 115. First turning to FIG. 2A, the components will be discussed from right to left, that is starting from chassis 115 and moving outward toward the bezel 104. The chassis 115 supports a latch lock engaging member, here shown as chassis defining a latch lock hole 200. The chassis also supports two hinge posts 202 and 204 which project outwardly from the chassis. The latch mechanism 110 also has a chassis hinge mount 210 which defines two hinge posts slots 212 and 214 located to receive the hinge posts 202 and 204, respectively. The chassis hinge mount 210 has a side wall 215, as better seen in FIG. 2B. The mount 210 also defines a cut-down neck portion 216 and an alignment pin 218.
The latch mechanism 110 includes an activation member, here illustrated as a leaf spring latch 220. The spring latch 220 includes a latch finger 222 which defines an elongated alignment slot 223 that receives alignment pin 218. The slot 223 is elongated along the longitudinal axis of finger 222 to allow the pin 218 to slide within slot 223, as well as move partially out of slot 223, during operation which allows the spring latch 220 to move relative to the chassis hinge mount 210. The latch finger 222 also has a blunt end 224 and an upper ramped edge 225 leading down to the blunt end. Perhaps as better shown in FIG. 2B, the spring latch 220 is attached to the interior of side wall 215 of the chassis hinge mount 210 by a pair of rivets 226 and 228, shown with their heads projecting from the latch spring in FIG. 2A.
Progressing on to the next component to the left, we see a bezel hinge mount 230 which attaches by rivets 232, 234, 236 and 238 to an interior wall of the bezel frame 105, as shown in FIG. 2B. Mount 230 also includes a pair of hinge plates 238 and 240 which each define holes to receive hinge pins 242 and 244, respectively. The chassis hinge mount 210 also has a pair of hinge pin flanges 246 and 248, which each define holes therethrough to receive hinge pins 242 and 244, respectively, as indicated by the dashed lines in FIG. 2A, and as best seen in FIG. 2B. The terms “hinge plate” and “hinge pin flange” may be considered as interchangeable terms, with the only differentiation herein being for the sake of clarifying the explanation as to which component is being referred to in a particular discussion.
FIG. 2A has several dashed lines and curved arrows which may need some explanation to give one the proper orientation of the components of the bezel latch mechanism 110. To show the orientation of the chassis hinge mount posts slots 212, 214 with respect to hinge posts 202 and 204, respectively, curved arrow 250 indicates that mount 210 needs to be rotated 90 degrees. Similarly, curved arrow 252 indicates that given the position of mount 210 in FIG. 2A, the spring latch 220 needs to be rotated 90 degrees so rivets 226, 228 may be inserted through side wall 215 of mount 210 before being received by the spring latch 220. The dashed lines in FIG. 2A indicate the various components that match together, such as dashed line 254 which indicates hinge pin 242 is to be received by the hole defined by hinge pin flange 246.
In the past, the front opening electronic enclosures used faceplates which were either, (1) hinged, or (2) of the snap-on variety. The hinged faceplates often took up necessary space in the service aisle during maintenance, where they could easily be bumped or damaged by service personnel. These hinged faceplates typically used a conventional house door type hinge, a gate hinge, a continuous hinge, or other permanently attached hinge, which prevented the faceplate from being removed if it was obstructing work or workers. The snap-on faceplates required complete removal before any of the internal components could be accessed even for a quick adjustment or check-up, such as to use the scrolling buttons 125 on motherboard 116.
The bezel latch mechanism 110, not only provides for a rapid hinged opening, but also for complete removal of the bezel 104 if desired. During normal operation, hinge posts 202, 204 reside within an upper portion of slots 212, 214, respectively (see FIG. 2A). After opening the spring-loaded latch 112 (FIG. 1), the bezel 104 may be swung open to the position of FIG. 2B where the latch finger 222 has disengaged lock hole 200, allowing service personnel to lift the bezel off of posts 202 and 204 (FIG. 2A) for removal from chassis 115. Thus, through the use of bezel latch mechanism 110, the bezel 104 may function as a hinged faceplate as well as a snap-off faceplate, depending upon the need at hand. Before moving on to a detailed explanation of the operation of the bezel latch mechanism 110, a further explanation of the spring latch 220 with respect to FIG. 2E may be helpful.
For further clarification, FIG. 2E shows one embodiment of the cross sectional shape of latch finger 222, with respect to the engagement of pin 218 and alignment hole 223. The blunt end 224 of the latch finger 222 extends outwardly at an angle from the portion of finger 222 where slot 223 resides, allowing the latch finger to better engage the lock hole 200 in the illustrated embodiment. The elongated nature of alignment slot 223 allows the alignment pin 218 to move longitudinally within slot 223, as indicated by arrow 256. Furthermore, the length of pin 218 allows it to move inwardly and outwardly from slot 223, as indicated by arrow 258 to facilitate flexing of the latch spring 220 during operation.
Referring briefly to FIG. 2A, to replace the bezel 104 after servicing, the post slots 212, 214 first receive hinge posts 202, 204 through their lower open mouths, and then as bezel 104 moves downwardly, perhaps under the force of gravity or under manual pressure, the posts come to rest within the upper portion of the slots, leaving the bezel pivotally attached to the chassis for hinged opening and closing. This reattachment operation is shown in FIGS. 2B-2D, with unattachment occurring the opposite order. In a beginning attachment phase shown in FIG. 2B, the posts 202, 204 are entering the mouths of slots 212, 214 (see FIG. 2A), respectively, and the latch finger 222 has not yet began to engage lock hole 200. In a transitional phase shown in FIG. 2C, posts 202, 204 are beginning to move upwardly along the vertical portion of slots 212, 214 (FIG. 2A), while the ramped edge 225 of latch finger 222 is beginning to gently engage lock hole 200.
A final, fully engaged state is shown in FIG. 2D, where posts 202, 204 have come to rest in the top portion of slots 212, 214 (see FIG. 2A), and the latch finger 222 is fully engaged within lock hole 200. As the final stage of FIG. 2D arrives, the spring action of latch 220 is felt by a person replacing bezel 104 when finger 222 fully engages lock hole 200, giving this person a positive tactile indication that hinge posts 202, 204 (FIG. 2A) are in the proper position for swinging bezel 104 shut. Thus, the latch mechanism 110 provides a tactile response for service personnel when the bezel 104 has been snapped back into place for a hinged closing. Similarly upon opening, the disengagement of the latch finger 222 from lock hole 200 is also felt, giving the person a tactile response that bezel 104 is ready to be removed from posts 202 and 204 (see FIG. 2A).
III. Enclosure Chassis with Air Dams:
FIG. 3 shows the chassis 115 of the illustrated embodiment of modular electronic enclosure 100 as including a midplane 300, which divides the chassis into a front portion 302 and a rear portion 304. The front portion 302 will be discussed first, followed by a discussion of airflow vents through chassis 115. In this embodiment, the front portion 302 is divided into an upper portion 306 and a lower portion 308 by deck 310. The lower portion 308 comprises a single compartment 312 which includes a pair of motherboard latch receptacles, one on the right side and the other on the left side, such as left latch receptacle 314 visible in the view of FIG. 3.
The upper portion 306 is divided into four compartments, here shown as adjacent fan compartments 316 and 316 a, and flanking power compartments 318 and 318 a. The fan compartments 316, 316 a each included a fan latch receptacle, such as receptacle 320 for left fan compartment 316, while the power compartments 318, 318 a each include a power latch receptacle, such as receptacle 321 for the left power compartment 318. Thus, the lower compartment latch receptacles 314 receive latches 122, while the fan compartment latch receptacles 320 receive latches 134, and the power compartment receptacles 321 receive latches 128 to removably secure the motherboard 116, the fan units 120, 120 a, and the power units 118, 118 a in place.
The compartments 318, 320, 320 a and 318 a are each separated by dividers 322, 324 and 326, respectively. Each of the dividers 322-326 defines a window 328 therethrough to allow air to flow between adjacent compartments. At the rear of the power compartments 318 and 318 a are electrical connectors 330 which engage mating electrical connectors (not shown) at the rear of each of the power units 118 and 118 a, respectively. Similarly, at the rear of fan compartments 316, 316 a are electrical connectors 332 which engage mating electrical connectors (not shown) at the rear of each of the fan units 116 and 116 a.
Before going into detailed description of airflow through the modular electronic enclosure 100, the various components which contribute to the airflow design are described with respect to the components with which they are associated. The big deck 310 defines therethrough a series of vent holes 334 located toward front portion of each of the fan compartments 316, 316 a, and another series of fan vent holes 336 located toward the rear portion of the fan compartments. It is apparent that while groups of circular or rectangular fan vent holes are illustrated herein, the vents may also be arranged as one or more vents slots, or in other geometric patterns or configurations depending upon the particular implementation employed. Similarly, while the compartments 312, 318, 316, 316 a and 318 a are shown as arranged into upper and lower portion 306, 308 other compartment divisions may be made within chassis 115, depending upon the desired implementation, while still employing the concepts described herein.
The chassis 115 includes four air dams 340, 342, 344 and 346, located near the entrances to compartments 318, 316, 316 a and 318 a, respectively. Each of the illustrated air dams 340-346 are of a flexible metal spring material which acts as a flap, although in some embodiments a flexible plastic or other similar material may be more suitable. When the upper portion modules 318, 316, 316 a and 318 a are pulled out of the chassis 115, the air dams 340-346 spring into their closed positions, as shown in FIG. 3, to prevent an airflow “short-circuit.” The simple one-piece design of air dams 340-346 used in this thermal design is believed to be unique, and may be used in other applications, to prevent unwanted airflow through a passageway, such as in a vending machine beverage can-catcher, or other air barriers for refrigeration, heating or ventilation protection when an item needs to occasionally pass through the passageway.
As mentioned the Background section above, earlier air dams were typically of the double hinged saloon-door style, or a horizontally hinged, vertically hung door which was gravity operated, similar to many inside/outside doggie doors, but these earlier designs only prevented 85% of airflow therethrough. In the illustrated embodiment, the air dams 340-346 have shown in testing to be 95% efficient in preventing airflow therethrough when the fan and power units 118, 116, 116 a and 118 a are removed from compartments, 316, 318, 316 a and 318 a. While the illustrated air dam 340 swings open toward the right, and air dams 342-346 swing open toward the left, which is convenient for the illustrated embodiment, although it is apparent that left swinging or right swinging air dams may be substituted therefor.
The midplane 300 of chassis 115 also defines a pair of airflow channels 348, located at the rear of each of the fan compartments 316, 316 a to allow airflow between the chassis front portion 302 and the chassis rear portion 304. Near the front of the rear portion 304, chassis 115 includes an air metering plate 350, which is ramped upward from the bases of airflow channels 348 toward the rear of chassis 115. As described in further detail below, the metering plate 350 may be replaced with metering plates of different sizes, orientations, and configurations to control airflow between the front and rear portions 302, 304 to accommodate for various cooling capacities required by the components housed therein. Thus, the modular electronic enclosure 100 may be upgraded for larger heat loads by varying the size and configuration of metering plate 350. The rear portion 304 of chassis 115 may define a series of vent holes 352 therein, to vent components housed within the chassis rear portion 304 (see FIG. 7), or alternatively, vent holes 352 may be defined by an upper portion of components housed within the rear portion 304 of chassis 115. The overall airflow design of the modular electronic enclosure 100 will be discussed in more detail after describing the various hot-swappable modular components 116, 118, 120, 120 a, 118 a housed therein.
IV. Hot-Swappable Modular Components:
FIG. 4 shows the motherboard 116 removed from chassis 115. The motherboard 116 includes an upper surface 400 of frame 124 which defines series of vent holes 402 therethrough toward the front thereof, and a series of vent holes 404, 406 which reside under vent holes 344 beneath the fan compartments 316, 316 a (FIG. 3), respectively. The motherboard frame upper surface 400 also defines a series of vent holes 408 therethrough toward the rear of the motherboard 116, which allow airflow from the motherboard through vent holes 336 of the fan compartments.
FIG. 5 shows power module 118 as having an electrical connector 500 which mates with connector 330 when the power module 118 is inserted into the power unit compartment 318. The power unit 118 a is constructed a similar fashion. Each power unit frame 130 has an interior sidewall 502 which defines a series of vent holes 504 therethrough to facilitate airflow from the power units 118, 118 a toward the fan modules 120, 120 a, respectively.
FIG. 6 shows one fan unit 120 as including an electrical connector 600 located toward the rear of the unit to engage electrical connector 332 when the fan unit is inserted into the fan compartment 316. The fan unit 120 a is constructed in a similar fashion. The frames 136 of the fan units 120, 120 a each have opposing side surfaces 602 and 604, which each may define a series of vent holes 606 therethrough for airflow through windows 328 of dividers 322-326. Each of the fan units 120 and 120 a may include a ventilation member, such as fan 610, the operation of which will be described in further detail below under the Airflow section.
Thus far, the CRU's residing within the front portion 302 of chassis 115 had been discussed. FIG. 7 shows thirteen CRU's 700-712 residing within the chassis rear portion 304, although it is apparent that in other implementations other modules may reside therein and be of different numbers and different configurations. Each CRU 700-712 has a handle 714 for inserting and extracting the unit from chassis 115. Most of the CRU's are input/output units, each having four pairs of input/output receptacles 716 (shown only on CRU module 712), such as those for receiving fiber-optic cables. In one embodiment, CRU's 703 and 704 are router interconnects, and CRU 700 is a maintenance port. Each of the CRU's 700-712 may include an electrical interconnect 718, which mates with an electrical interconnect (not shown) the located underneath the air metering plate 350 along the rear surface of midplane 300.
The chassis 115 also supports a pair of electrical power interconnects 720 and 720 a, here shown located above CRU's 700 and 712. The interior of the chassis rear portion 304 is divided into the thirteen compartments, such as compartments 722 and 724 which are separated by divider 726 to receive CRU's 711 and 712, respectively. Each of the CRU's 700-712 has an exposed face which defines a series of vent holes 730 therethrough, and an upper surface which defines another group of vent holes 732 therethrough. The lower surface of each of the CRU's 700-712 may also define vent holes for airflow between the CRU's and chassis vent holes 734 defined by a floor 736 underneath each of the CRU compartments, such as compartments 722 and 724. The floor 736 is preferably elevated by footing walls, such as wall 738, to define an airflow passageway 740 underneath floor 736. The chassis 115 also has a rear wall 742 located above CRU's 700-712, which besides being a convenient location for mounting interconnects 720, 720 a, and displaying various manufacturing and certification indicia, also serves as an air deflection wall, as described in greater detail below with respect to FIG. 9.
The chassis 115 illustrates only one embodiment of a modular electronic enclosure, and the various components housed within upper and lower portions 306, 308 of front portion 302 as well as the components housed within the rear portion 304 are merely shown by way of example, and other arrangements for the compartments, and placement of the midplane 300, if used, may be employed. These modular components, as mentioned above, are known as customer replaceable units or CRU's, and may be replaced without disengaging power from modular electronic enclosure 100. Even the dual fan units 120, 120 a may be replaced without de-energizing the electronic enclosure 100, while one fan unit is replaced, the other continues to provide cooling. The same holds true for the dual power units 118, 118 a, one of which may be replaced while the other continues to power the CRU's remaining within enclosure 100. Additionally, through the use of the compartment dividers 310, 322-326 and 726, the CRU's require no effort in alignment prior to inserting each module, such change-outs are speedily accomplished.
V. Airflow Cooling and the Metering Plate:
FIG. 8 shows a top view of the airflow cooling design of the illustrated modular electronic enclosure 100. Air entering through the air inlet ports 138 of fan units 120, 120 a is indicated by arrows 800, 800 a, with airflow through the majority the fan compartments toward fans 610, 610 a is indicated by arrows 802, 802 a, respectively. Air entering through the inlet ports 132 of power units 118, 118 a is indicated by arrows 804, 804 a, which then traverses through windows 328 of dividers 322 and 326 into fan units 610, 610 a. Pressurized air leaving fan units 610, 610 a is indicated by arrows 808, 808 a which passes through the airflow channels 348 of midplane 300 and across the air metering plate 350 (FIG. 3). The air metering plate 350 ramps upward toward the rear of the chassis, which results in pressurizing the air further, by constricting the airflow passageway. Arrows 810, 810 a show the airflow pattern across the metering plate 350 (omitted for clarity from the view of FIG. 8) in the chassis rear portion 304.
The metering plate 350 is replaceable to allow for system upgrades which may impose larger heat loads on the enclosure 100. For example, by increasing the size of metering plate 350, the airflow streams 810, 810 a are further pressurized and air velocity is increased to move the heat away faster. In other embodiments, the ramp angle of the metering plate 350 may be varied, raising the ramp to increase velocity, and lowering the ramp to decrease air velocity. In other embodiments, the configuration of the trailing edge of ramp 350 may be varied, such as by adding scallops or cut-out areas to increase airflow across some of the CRU's 700-712 and decrease airflow across others.
FIG. 9 shows the airflow passageways through the fan unit 120 and motherboard 116, as arrows 800, 802 and 900, respectively. Warm air from the motherboard 116 passes upward through vent holes 336 in the deck 310, and then into fan 610. Arrow 904 shows pressurized air leaving fan 610, which is then directed through channel 348, as shown by arrow 906, then over the metering plate 350 and into the chassis rear portion 304. The chassis rear wall 742 deflects the airflow downwardly through vents 732 and into the interior of CRU's 700-712. The warmed air may vent outwardly through the faceplates vents 730, or downwardly through vents 734 in the floor 736, to exit through the lower airflow passageway 740.
This airflow design places the fans in the middle of the electronic enclosure to pull in cool air through the front CRU modules 316-320 a and push pressurized air through the rear CRU modules 700-712 after which the warm air is vented to atmosphere. This unique airflow design facilitates the high-density packing of CRU's within chassis 115, which is believed today the highest density available for fiber input/output interconnects 716, here capable of carrying a large number of cables, while still maintaining a modular, hot swappable design for the CRU's. In the illustrated embodiment, the overall design is 5.25 inches tall, which is equivalent to three units (3U) high for electronic designers, while still fitting into the 19 inch wide EIA standard rack 102. As mentioned above, the airflow flow concepts described herein may be easily adapted to other arrangements and configurations of CRU's, while still maintaining the hot swapping capability of the CRU's.

VI. CONCLUSION

Thus, a modular electronic enclosure 100 having a unique cooling design and useful in practicing a unique cooling method for controlling heat generated by various CRU's house therein. Every CRU may be removed or serviced without disrupting the airflow through the enclosure, including the fan modules 120 or 120 a, in part because of the spring-loaded air dams 340-346 (shown open in solid lines, and closed in dashed lines in FIG. 8). The air dams 340-346 restrict airflow into the enclosure when a fan unit 120, 120 a or a power unit 118, 118 a is removed from chassis 115. Additionally, this unique cooling design allows for a much higher density arrangement of the input/output CRU's 700-712 than currently available in other enclosures.
The modular hot swappable nature of the CRU's, allowing interchange without the need to power down the enclosure, also provides for replaceability from the front and rear of the enclosure, without requiring removal from the mounting racks 102 and without requiring removal of a top cover from the chassis. In this manner, the CRU's are quickly replaced, with interconnect alignment being facilitated by the compartment dividers 310, 322-326 and 726. Bezel latch mechanism 110 allows for a quick hinged opening of the bezel 104, while also allowing the bezel 104 to be quickly removed and quickly replaced when desired. The tactile feedback provided by the spring latch 220 assists a person in determining when the post slots 212, 214 are fully engaged on the hinge posts 202, 204 when replacing the bezel.
The foregoing has described the principles, embodiments and modes of operation of the present invention. However, the invention should not be construed as being limited to the particular embodiments discussed. The above-described embodiments should be regarded as illustrative rather than restrictive, and it should be appreciated that variations may be made in those embodiments by workers skilled in the art without departing from the scope of the present invention as defined by the following claims.

Claims

1-29. (canceled)

30. A latch mechanism for an enclosure to removably attach a door to a pair of hinge posts supported by a frame, comprising:

a door hinge mount configured for attachment to the door;

a frame hinge mount defining a pair of the post slots configured to releasably receive the pair of hinge posts;

hinge pins pivotally attaching the door hinge mount to the frame hinge mount; and

a spring latch supported by the frame hinge mount and having a latch finger which engages a latch lock engaging member supported by the frame when the post slots have fully received the pair of hinge posts.

31. The latch mechanism of claim 30, wherein:

the pair of post slots are each defined with an open mouth, a hooked portion, and an upright portion joining the mouth with the hooked portion, with the pair of hinge posts entering and exiting the post slots through the mouth thereof, and resting within the hooked portion thereof when the post slots have fully received the pair of hinge posts; and

the latch finger has a ramped portion which engages a surface of the latch lock engaging member as the hinge posts move through the upright portion of the post slots.

32. The latch mechanism of claim 30, further comprising:

an alignment member supported by the frame hinge mount; and

wherein the latch finger defines an alignment slot which slidably receives the alignment member during pivoting of the door hinge mount relative to the frame hinge mount.

33. The latch mechanism of claim 30, wherein:

the pair of post slots are each defined with an open mouth, a hooked portion, and an upright portion joining the mouth with the hooked portion, with the pair of hinge posts entering and exiting the post slots through the mouth thereof, and resting within the hooked portion thereof when the post slots have fully received the pair of hinge posts;

the latch lock engaging member comprises a latch lock hole defined by the frame to have an upper surface;

the latch finger has a ramped portion which engages latch lock hole upper surface as the hinge posts move through the upright portion of the post slots;

an alignment member supported by the frame hinge mount; and

34. An apparatus for selectively closing an enclosure defined in part by opposing first and second side walls and upper and lower walls, comprising:

an air dam of a flexible metal spring material having first and second opposing edges, and upper and lower edges configured to extend between said upper and lower walls; and

an attachment member which attaches said first edge to the first side wall;

wherein the air dam is biased into a closed position with said second edge engaging the second side wall, and wherein air dam is forced into an open position with said second edge engaging the first side wall when an item passes therethrough when moving through the compartment.

35. An apparatus according to claim 34, wherein the air dam is moved toward an interior of the compartment when moving from the closed position to the open position when said item enters the compartment.

36. An enclosure for slidably and replaceably receiving plural first and plural second replaceable units, comprising:

a chassis having opposing front and rear faces;

a midplane member having opposing front and rear surfaces supported by the chassis to define a front portion between the midplane member and the front face, and a rear portion between the midplane member and the rear face;

plural first electrical connectors supported by the midplane front surface to couple with mating electrical connectors of said plural first replaceable units when installed through the chassis front face; and

plural second electrical connectors supported by the midplane rear surface and to couple with mating electrical connectors of said plural second replaceable units when installed through the chassis rear face.

37. The enclosure of claim 36, further comprising a deck member located to divide the front portion into upper and lower portions which each receive some of said plural first replaceable units.

38. The enclosure of claim 36, further comprising a ventilation unit configured to pull cooling air through the front face and the first replaceable units, pressurize said cooling air, and exhaust said pressurize cooling air through the plural second replaceable units.

39. The modular electronic enclosure of claim 38, wherein:

the chassis defines plural separate compartments configured to slidably receive individual ones of the plural first and plural second replaceable units; and

the electronic enclosure further comprises separate air dams located within at least some of said plural separate compartments to inhibit entrance of cooling air therein when an associated replaceable unit is removed therefrom.

40. The modular electronic enclosure of claim 36, further comprising:

a bezel door configured to cover the chassis front face when in a closed state; and

a bezel latch mechanism configured to pivotally attach the bezel door to the chassis for movement between the closed state and an open state, with the latch mechanism also being configured for removably attaching the bezel door to the chassis in the open state;

wherein the bezel latch mechanism further comprises a spring latch configured to provide tactile feedback when the bezel door is reattached to the chassis for pivotal movement from the open state to the closed state.