BR202017007096U2 - SAFE, TRANSPORTABLE EQUIPMENT WITH SIDE AND FRONT INTERNAL INSULFLAMING TO RACKS AND COOLING MEDIA - Google Patents

Description

SAFE TRANSPORTABLE EQUIPMENT WITH FRONT AND SIDE INTERNAL INSULFLATION TO RACKS AND MEANS OF COOLING 1. TECHNICAL FIELD - This utility model is concerned with an improvement in the process of chilled air insulation through equalization plenums and vertical front outlet to the equipment to be cooled. in secure transportable data centers. 2. Data Processing Center, or Data Center, is an environment designed to concentrate servers, data processing and storage equipment, and network asset systems such as switches, routers, and others. Therefore, it is considered the critical system of companies. 3. TECHNICAL BACKGROUND - In order to house thousands of servers and databases, and to process large amounts of information, equipment is usually mounted in metal racks or cabinets. They have fire protection as well as rack cooling systems to maintain a stable temperature. In most cases, they are located in large warehouses with restricted employee access for security reasons. 4. These spaces are critical to services and activities in various sectors of the economy: energy, lighting, telecommunications, the Internet, transportation, urban traffic, banking, security systems, public health, entertainment, and many others. Life in most cities depends on the smooth running and availability of one or several data centers. 5. Good cooling and power systems ensure proper operation of equipment and systems within a data center. Cooling is meant to keep the room temperature at the right levels so that everything runs smoothly and without very large oscillations, which is extremely detrimental to Data Center operation. 6. Getting equalized chilled air straight to the front portion of the racks at the same temperature is a big problem to solve. 7. A major problem is that with the common system the equipment has to have a higher floor height making the equipment unviable to manufacture beyond the standard transport height. 8. BRIEF DESCRIPTION OF THE PROCESS - The process improvement mentioned here keeps the pressure and velocity maintained, unlike other systems that depend on air rise. 9. This process has the advantage that when this air enters the inner plenum due to the speed, flow and pressure that this machine applies, it creates a positive pressure inside the inner plenum by pushing the chilled air through the baffle openings. Accordingly, the plug-and-play air conditioning machine coupled to a lower plenun equalizes the air and duct and takes it to an inner plenun. 10. This positive air flow in the cold aisle brings the same amount of refrigerated air to the front of the racks. 11. Therefore the system achieves a better distribution of cold air in the racks, making the whole equipment smaller. 12. Another advantage is that the rack support floor can perform electrical maintenance, detection, fire extinguishing without loss of system efficiency as the supply system is not in the same area as these disciplines. This also applies to the ceiling because it has the same facilities. 13. The continuous and well-distributed flow of this system, in addition to better rack cooling, improves the performance of air conditioning machines, as they can be sized for a load below those normally required by standard air conditioning systems. lower insufflation. 14. The cold air that in common systems is blown into the rack room from the bottom of the data center in this system is from the front of the rack. This is due to the creation of distribution equalization plenums and return plenums. 15. The plug-and-play air conditioner is housed in a structured plenunum box which through a flanged coupling is joined causing the cold air coming from the machine to be downwardly inflated into the plenun which by abrupt expansion decreases the air velocity equalizing it within the plenun. 16. In a continuous system this equalized freezing air is routed to a directional curve duct which coupled to a fire damper inflates the freezing air to another inner plenum. 17. This inner plenum, which can also be characterized as an abrupt expansion, slows the air velocity so that it is distributed evenly within the inner plenun. 18. An inclined flow plate with deflecting fins directs the equalized air to a perforated wall that is intended to be a directed air path to the cold aisle. 19. Note that the supply system has several plenums that through expansions provides an equalized air for front feeding of the racks. 20. Upon arrival of cold air in the cold aisle through forced circulation, since the inner plenum aisle has a normal positive inflation pressure, it tends to pass through the racks by cooling them. 21. After cooling this less cold air tends to rise to the holes in the interliner causing all this air from the system routed through a duct with another damper to cut fire. 22. At the end of the cycle the air passing through the damper is equalized again, however, to return the air conditioner located below that upper plenum and also fixed by flanges. 23. DRAWINGS - In addition to the present description in order to gain a better understanding of the features of the present and according to a preferred practical embodiment thereof, accompanying the accompanying description is a set of drawings, where, by way of example, although 24. Figure A shows a 3D view of the overall system indicating each plenum providing the cold air path as well as the positioning of the air machine and the racks. 25. Figure B shows the area of the lower plenum of insufflation as well as the damper duct routing to the inner side of the data center. Where AA details the observation point without the rack room closing wall, BB represents the plug and play air conditioner room, CC shows an elevated view where the DD portion illustrates the internal area for rack and EE allocation. the inner area of the anteroom. It also shows an FF profile view, a GG plan and an HH perspective. 26. Figure C shows the inner plenum by directing the air to the front of the racks as well as the cold air through the racks and into a warm aisle located at the rear of the racks. Where AAA details the KK engine room observation point with detail of the engine room air inlet opening for the JJ rack room, MM shows an elevated view where the LL portion represents the interior area for rack rental, NN illustrates the inner area of the anteroom. It also shows a profile view 00, with emphasis on PP illustrating the front air insufflation to the racks and QQ shows the rising return air, where RR shows the cold aisle, SS shows the hot aisle, TT the opening. rack-to-an-room air intake, a UU plant with normal air flow between the racks is also presented, VV illustrates the area intended for the racks, YY the inner insulation plenun, XX the front air insulation to racks, WW is the rising rising air, and a 3D view called ABC is also illustrated. 27. Figure D shows the final stage of the cycle, where air from the rear of the racks is taken up by the ceiling and through a ducted damper forwards the air to an equalization plenum. Where QWX looks at an elevation view, CCC details the engine room observation point, DDD illustrates the rising return air, WYK shows the interior area of the anteroom and rack allocation, XYZ represents the room space MON demonstrates a profile view, SOS illustrates the hot aisle, BUT presents a normal airflow plan of the rack room / inter-ceiling / upper plenun where ZYX is the inner insulating plenun, GUS shows the opening of the Downstream air inlet, DIM shows upward return air and RER displays a 3D view where AEF shows the inter-lining area and BOX represents the engine room space. 28. DETAILED DESCRIPTION OF THE PROCESS - With reference to the illustrated drawings, this transportable data center, containing lower insulating equalization plenum (01), internal plenun (02), return equalization upper plenun (03), air conditioning machine (04), racks (05), coupling flanges (06), lower plenun (07), connecting intermediate duct (08), inlet curve (09), fire damper (10), flow plate (11) baffle fins (12), baffle plates (13), architectural grid (14) and interlayer (15); said secure data center having a watertight rack room which through an external insulating duct (Figure B / 08, 09 and 10) receives the equalized air from a lower plenum (Figure B / 07) which was fed by a Wall-mounted downward-type air blower (Figure A / 04). Air received externally by the outer insulating duct (Figure B / 08, 09 and 10) is distributed through the inner plenum (Figure C) directed vertically by the flow plate, baffles and deflector plate (Figure C / 12 and 13). Air directed vertically by the flow plate, baffles and deflector plate (Figure C / 12 and 13) will be facing the racks (Figure A / 05) equalizing the cold aisle so that through a directed flow will cool of the same. The chilled cooling air passes between the equalized racks (Figure A / 05) in the hot aisle and an upward path into an inter-ceiling plenum (Figure D / 15) through openings. The plenum between lining (Figure D / Position 15) receives all exchange air that through a ducted damper (Figure D / 10) forwards this air which is now called return air to a higher return equalization plenun (Figure D / 10). D / 03). The upper equalization plenum of the return equalization (Figure D / 03) equalizes all the return air and by a movement caused by dust a negative pressure from the Wall-Mounted air conditioner (Figure A / 04) takes the return air into this machine and so the process is complete. 29. It is important to understand that the present invention does not limit its application to the details and steps described herein. Being capable of other embodiments and of being practiced or performed in a variety of ways, it is understood that the terminology employed is for the purpose of description rather than limitation.

Claims (1)

1) SAFE TRANSPORTABLE EQUIPMENT WITH SIDE AND FRONT INTERNAL INSULFLATION TO RACKS AND COOLING FEATURES characterized by such data center having lower insulation equalization plenun (01), internal plenun (02), upper return equalization plenun (03), machine air conditioning (04), racks (05), coupling flanges (06), lower plenun (07), connecting intermediate duct (08), inlet curve (09), fire damper (10), flow plate (11), deflecting fins (12), deflecting plates (13), architectural grid (14) and inter-lining (15) that cool through an external insulating duct (Figure B / 08, 09 and 10) that receives the equalized air from a lower plenum (Figure B / 07) fed by a downwardly inflating air machine (Figure A / 04); where air received externally by the outer insulating duct (Figure B / 08, 09 and 10) is distributed through the inner plenum (Figure C) directed vertically by the flow plate, fins and deflector plate (Figure C / 12 and 13); then the air directed vertically by the deflector flow plate, fins and plate (Figure C / 12 and 13) will be facing the racks (Figure A / 05) equalizing the cold aisle so that through a directed flow to cool down of the same; then the chilled cooling air passes between the equalized racks (Figure A / 05) in the hot aisle and an upward path into the inter-plenum plenum (Figure D / 15) through openings; the plenum between lining (Figure D / 15) receives all the exchange air that through a ducted damper (Figure D / 10) forwards this air which is now called return air to a higher return equalization plenun (Figure D / 03); the upper return equalization plenun (Figure D / 03) equalizes all return air and by a movement caused by a negative pressure from the air conditioner (Figure A / 04) takes the return air into this machine.