JP5268855B2 - Rack and information processing equipment accommodation - Google Patents

Description

  The present invention relates to a rack and an information processing equipment accommodation facility.

  Patent Document 1 below describes an information processing equipment housing facility that actively cools information processing equipment by introducing cooling air into a rack that houses information processing equipment at a high density. In addition, when an axial fan or the like is provided in each information processing device, it has been proposed to limit an increase in the wind pressure of the cooling air to be supplied in order to prevent overload of the axial fan.

JP 2007-316989 A

  However, discharging a part of the cooling air without using it for cooling the information processing equipment wastes part of the energy consumed in the stage of generating the cooling air.

  Therefore, in order to solve the above problems, as a first aspect of the present invention, a rack main body that accommodates an information processing device having an exhaust fan, an introduction portion that introduces cooling air into the front surface of the rack, and the cooling air to the rack main body The exhaust air that has been introduced and exhausted by the exhaust fan is discharged from the back of the rack to the outside, and a part of the cooling air supplied to the introducing portion is exhausted, so that the cooling air that is introduced into the rack body is exhausted. A rack is provided that includes a pressure adjustment unit that adjusts the total pressure, and a circulation unit that circulates cooling air discharged from the pressure adjustment unit to the introduction unit.

  In addition, as a second aspect of the present invention, a rack body that accommodates an information processing device having an exhaust fan, a cooling air supply unit that supplies cooling air, and a cooling air supplied from the cooling air supply unit are connected to the front surface of the rack body An introduction section that introduces the cooling air into the rack body, an exhaust section that exhausts the cooling air exhausted by the exhaust fan from the back of the rack, and a portion of the cooling air supplied to the introduction section. Information including a pressure adjusting unit that restricts an increase in the total pressure of the cooling air introduced into the rack body by discharging from the introducing unit, and a circulating unit that circulates the cooling air discharged from the pressure adjusting unit to the introducing unit. Processing equipment accommodation is provided.

  The above summary of the present invention does not enumerate all necessary features of the present invention. Further, a sub-combination of these feature groups can be an invention.

1 is a perspective view of the entire accommodation facility 100. FIG. FIG. 3 is a perspective view excluding a part of the accommodation facility 100. FIG. 3 is a perspective view excluding a part of the accommodation facility 100. FIG. FIG. FIG. FIG. 3 is a cross-sectional view of an aspirator 180. FIG.

  Hereinafter, the present invention will be described through embodiments of the invention, but the following embodiments do not limit the invention according to the claims. In addition, not all the combinations of features described in the embodiments are essential for the solving means of the invention.

  FIG. 1 is a perspective view of the entire accommodation facility 100. The accommodation facility 100 is constructed in the accommodation room 110 arranged inside the building, and includes an air conditioner 120, a rack body 130, a cooling air introduction part 150, and a circulation part 170.

  The storage chamber 110 has a floating floor 114 spaced from a slab 112 of the housing. As a result, an underfloor duct 113 for circulating cooling air is formed between the slab 112 and the floating floor 114. The air conditioner 120, the rack body 130, the cooling air introduction unit 150, and the circulation unit 170 are placed on the floating floor 114.

  In the storage chamber 110, a pair of air conditioners 120 is disposed in the vicinity of the pair of side walls facing each other. Each of the air conditioners 120 sucks and cools the air inside the storage chamber 110 from the recovery unit 122 on the upper surface, and then jets it into the underfloor duct 113 as cooling air. Thereby, the cooling air is pumped to the cold aisle 102 described later through the underfloor duct 113.

  The air conditioner 120 also includes an outside air introduction unit 124 that communicates with the outside of the storage chamber 110. Therefore, the air conditioner 120 can also introduce the outside air in addition to the air sucked from the recovery unit 122 when the temperature of the air in the other room or the outside air is sufficiently low. Thereby, the energy consumed when the air conditioning apparatus 120 cools cooling air can be suppressed.

  Between the pair of air conditioners 120, rack bodies 130 facing each other are arranged. Each rack body 130 is vertically long and can accommodate a plurality of cases 140. In the illustrated state, a plurality of cases 140 are accommodated in each of the rack main bodies 130. Exhaust fans 142 are respectively disposed at the rear ends of the cases 140 visible in the drawing. A place where the case 140 is not mounted in the rack body 130 is sealed with a blank panel 148.

  By arranging the rack main bodies 130 adjacent to each other so as to face each other, a large number of rack mount devices can be stored in the storage chamber 110 with high density. The illustrated rack main body 130 has a height of 42 U that can accommodate up to seven 6 U-size cases 140, for example. By arranging such a row in which eight rack bodies 130 are arranged face to face, 112 6U-sized cases 140 can be accommodated.

  The upper surface of the cold aisle 102 formed between the rack bodies 130 facing each other is sealed with a top cover 152. Further, the side surfaces of the cold aisle 102 are each sealed by a pair of doors 154. As a result, the top cover 152 and the door 154 form a cooling air introduction part 150 that encloses the cold aisle 102 in a region on the front side of each of the rack main bodies 130, and the cooling air is efficiently used for cooling the inside of the rack main body 130. Use it often. The circulating portion 170 includes a plurality of circulating ducts 172 that allow the inside of the top cover 152 to communicate with the underfloor duct 113. Elements other than the circulation duct 172 in the circulation part 170 do not appear in this figure.

  FIG. 2 is a perspective view excluding a part of the accommodation facility 100. That is, FIG. 2 shows a state in which the circulating duct 172 on the near side in the drawing is removed from the accommodation facility 100 shown in FIG. Elements common to those in FIG. 1 are denoted by the same reference numerals and redundant description is omitted.

  In FIG. 2, it can be seen that the plurality of rack bodies 130 accommodate different numbers of cases 140, respectively. In the state shown in the figure, an empty space is arranged at the upper end of the rack body 130. However, an empty space may be arranged in the middle step or the lower end step. However, when the stability of the rack body 130 is taken into consideration, it is preferable to arrange an empty space in the upper stage.

  Each of the cases 140 accommodated in the rack body 130 has an exhaust fan 142 that exhausts hot air inside the case 140. Thereby, the hot air discharged from the case 140, that is, the exhaust of the information processing apparatus, forms the hot aisle 104 in which the hot air is distributed on the back surface (the front side and the back side in the drawing) of the rack body 130. The hot air discharged to the hot aisle 104 is recovered from the recovery unit 122 to the air conditioner 120, cooled, and becomes cooling air again.

  In FIG. 2, the pressure adjusting vent 160 appears on the side surface of the top cover 152 due to the removal of the circulating duct 172. Similarly, a plurality of vent holes 118 appear in the floating floor 114 by removing the reflux duct 172.

  The pressure adjusting vent 160 communicates with the inside of the top cover 152. The vent hole 118 communicates with the underfloor duct 113. Thereby, when the circulating duct 172 is mounted between the pressure adjusting vent 160 and the vent hole 118, the cold aisle 102 inside the top cover 152 and the underfloor duct 113 communicate with each other.

  FIG. 3 is a perspective view excluding a part of the accommodation facility 100. That is, FIG. 3 shows a state where the front rack body 130 and the top cover 152 are further removed from the accommodation facility 100 shown in FIG. Elements common to those in FIG. 1 are denoted by the same reference numerals and redundant description is omitted.

  In FIG. 3, it can be seen that the grating portion 116 is arranged between the rows of the plurality of rack main bodies 130 installed on the floating floor 114. The grating portion 116 is formed of a steel material assembled in a lattice shape, and allows the upper surface of the floating floor 114 and the underfloor duct 113 to communicate with each other. As a result, the cooling air supplied from the air conditioner 120 to the underfloor duct 113 is pumped from the grating 116 to the front of the rack body 130 to form the cold aisle 102.

  Moreover, since the grating part 116 has high intensity | strength, even if a person or equipment mounts on top, it does not interfere. As a result, the user can maintain the rack main body 130 on the grating unit 116 while blowing the cooling air 116 from the grating unit 116.

  FIG. 4 is a cross-sectional view of the accommodation facility 100. Also in FIG. 4, the same reference numerals are assigned to the same elements as those of the accommodation facility 100 illustrated in FIGS. 1 to 3, and redundant descriptions are omitted.

  Cooling air is pumped from the air conditioning apparatus 120 (not shown) to the underfloor duct 113 of the storage chamber 110. A grating 116 is disposed on the floating floor 114 between the rack bodies 130 facing each other. Accordingly, the cooling air is ejected from the grating portion 116 to the cooling air introduction portion 150 to form the cold aisle 102.

  In the drawing, a plurality of cases 140 are accommodated in the rack body 130 located on the side of the cold aisle 102. Each case 140 is supported by the rack body 130 by fixing its front panel 144 to a rack rail (not shown) of the rack body 130. Each case 140 has a plurality of blade servers 146 mounted in a direction orthogonal to the bottom plate of the case 140 and the front panel 144.

  Each of the front panels 144 of the case 140 has a louver, and introduces cooling air into the case 140 from the cold aisle 102 formed between the rack bodies 130. The exhaust fan 142 disposed at the rear end of the case 140 cools the blade server 146 inside the case 140 and discharges the cooling air that has become hot air to the back side of the rack body 130.

  A space in the rack body 130 in which the case 140 is not accommodated is sealed with a blank panel 148. Accordingly, the cooling air is prevented from being discharged from the cooling air introduction unit 150 without contributing to the cooling of the blade server 146.

  Note that the information processing device accommodated in the rack body 130 is not limited to the blade server 146. For example, in addition to communication devices such as switches, hubs, and routers, UPS (uninterruptible power supply), operation devices such as a keyboard, and display devices may be accommodated together.

  The cooling air introduction section 150 is provided on the front surface of the rack body 130 in order to introduce the cooling air from 116 into the rack in which the information processing apparatus is accommodated. The cooling introduction part 150 is a space formed by being covered with an opposing rack, an opening / closing door, and a top cover. Note that the cooling air introduction section 150 may be formed by a single rack and a wall or a ceiling, instead of the facing racks.

  The upper part of the cooling air introduction part 150 is sealed with a top cover 152. As a result, the cooling air pumped into the cooling air introduction section 150 is exhausted by the exhaust fan 142 exclusively through the case 140. Therefore, the cooling air can be efficiently used for cooling the blade server 146.

  A plurality of pressure adjusting vents 160 are disposed on the side surface of the top cover 152. The pressure regulating vent 160 includes an opening 162, a hinge 164 and a flap 166. The opening 162 is provided through the top cover 152 and allows the inside and outside of the cooling air introduction unit 150 to communicate with each other. The hinge 164 is disposed above the opening 162 on the outer surface of the top cover 152, and suspends the flap 166 in a freely rotatable manner.

  The flap 166 suspended from the hinge 164 is formed of, for example, a flexible sheet member. The flap 166 seals the opening 162 when receiving no external force, and bends according to the received pressure when the air pressure or wind pressure of the cold aisle 102 increases. As a result, cooling air is discharged from the inside of the top cover 152.

  Here, the flap portion 166 is designed and adjusted so that the air pressure and wind pressure of the cold aisle 102 are within a given range. As a result, the total pressure of the cooling air in the cooling air introduction unit 150 is restricted from exceeding the opening pressure of the flap 166, and the air pressure and wind pressure of the cold aisle 102 are prevented from significantly increasing.

  For example, when the load on the blade server 146 is greatly reduced at the business end time of the company, a large number of the exhaust fans 142 are stopped all at once, and the cooling air discharge amount from the cooling air introduction unit 150 is reduced. For this reason, if the total pressure of the cooling air in the cooling air introduction unit 150 becomes excessively large, an unexpected load may be applied to the exhaust fan 142. Also from this point, it is preferable that the excessive circulation of the cooling air is limited.

  The cooling air discharged from the pressure adjustment vent 160 is guided to the underfloor duct 113 through the circulation duct 172. Here, the circulating portion 170 including the circulating duct 172 further includes an axial fan 174, a check valve 176, and a heat insulating material 178.

  The axial fan 174 generates a pressure that flows from the pressure adjusting vent 160 side toward the vent hole side with respect to the cooling air inside the circulating duct 172. As a result, the cooling air discharged from the pressure adjusting vent 160 is returned to the underfloor duct 113 and finally supplied to the cooling air introduction unit 150 again. The check valve 176 prevents the cooling air from flowing backward from the underfloor duct 113 to the circulating duct 172.

  As described above, by providing the circulation unit 170, the cooling air discharged from the cooling air introduction unit 150 is not wasted without contributing to the cooling of the blade server 146 even though the air conditioner 120 is generated. Can be used without The heat insulating material 178 prevents the cooling air flowing through the circulating duct 172 from being heated by the hot air flowing through the hot aisle 104. Thereby, the energy efficiency of the accommodation equipment 100 whole can further be improved.

  In the above example, the rack main body 130 having a structure in which the front panel 144 of the case 140 is mounted on the rack rail is described. However, the structure of the rack main body 130 is not limited to the structure shown in the figure. For example, the rack main body 130 may have a structure having a plurality of shelf plates on which servers having individual housings are placed.

  Further, the server accommodated in the rack main body 130 is not necessarily the blade server 146 accommodated in the case 140. For example, instead of the blade server 146, a structure in which a server having an individual housing is directly mounted on a rack rail may be employed.

  FIG. 5 is a cross-sectional view of a housing facility 100 having another structure. However, the same reference numerals are given to the same elements as those of the accommodation facility 100 shown in FIGS. 1 to 4, and redundant description is omitted.

  In the accommodation facility 100, the circulating portion 170 includes a blank panel 148 having a pressure adjustment vent 160. On the other hand, the pressure adjusting vent 160 is not disposed on the top cover 152. For this reason, the upper end of the circulation duct 172 communicates with the back surface of the blank panel 148 provided with the pressure adjusting vent 160 instead of the top cover 152.

  With such a structure, the structure of the top cover 152 can be simplified, and the height of the top cover 152 can be reduced. Further, by replacing the blank panels 148 according to the number of cases 140, blade servers 146, etc. accommodated in the accommodation facility 100, the exhaust capacity of the pressure regulating vent 160 can be set appropriately.

  The accommodation facility 100 may have a structure in which the top cover 152 having the pressure adjusting vent 160 and the blank panel 148 having the pressure adjusting vent 160 are used in combination. Thereby, the exhaust resistance of the cooling air in the pressure regulation vent 160 can be lowered, and the response speed of the pressure adjustment of the cooling air introduction part 150 can be improved.

  FIG. 6 is a cross-sectional view of a storage facility 100 having another structure. However, the same reference numerals are given to elements common to the accommodation facility 100 shown in the other drawings, and redundant description is omitted.

  In the accommodation facility 100, the circulation part 170 is disposed inside the cooling air introduction part 150. The reflux duct 172 has a plurality of pressure adjusting vents 160 at the upper end. The lower end of the reflux duct 172 communicates with the underfloor duct 113 through a part of the grating portion 116.

  The pressure regulating vent 160 includes an opening 162, a hinge 164 and a flap 166. The opening 162 allows the cooling air introduction part 150 to communicate with the inside of the circulating duct 172. The hinge 164 is disposed above the opening 162 inside the circulating duct 172. The flap 166 is suspended from the hinge 164 so as to be rotatable.

  With the above structure, when the total pressure of the cooling air rises inside the cooling air introduction section 150, the flap 166 rotates against its own weight, and a part of the cooling air is discharged to the circulation duct 172. . Thereby, the total pressure (atmospheric pressure and wind pressure) of the cooling air in the cooling air introduction unit 150 is prevented from rising beyond the opening pressure of the flap 166.

  In addition, with such a structure, the circulating duct 172 can be significantly shortened. Further, since the circulating duct 172 passes through the cold aisle 102 in the cooling air introduction section 150, the heat insulating material 178 can be omitted.

  In addition, since the circulating portion 170 including the pressure adjusting vent 160 is integrated, the circulating portion 170 can be easily added to the accommodation facility 100 that does not include the circulating portion 170. Furthermore, the number of circulating parts 170 to be installed can be easily adjusted according to demand.

  FIG. 7 is a cross-sectional view of a storage facility 100 having another structure. However, the same reference numerals are given to elements common to the accommodation facility 100 shown in the other drawings, and redundant description is omitted.

  Also in the accommodation facility 100, the circulating portion 170 having a plurality of pressure adjusting vents 160 at the upper end is disposed inside the cooling air introduction portion 150. The pressure adjustment vent 160 has a common structure with the pressure adjustment vent 160 shown in FIG.

  On the other hand, the lower end of the circulating duct 172 is sealed, and a plurality of aspirators 180 are arranged instead of the axial fan 174 and the check valve 176. Each of the aspirators 180 is arranged along the flow of cooling air ejected from the grating unit 116.

  FIG. 8 is a cross-sectional view of the aspirator 180. The aspirator 180 includes a venturi tube 182 and an introduction tube 184.

  The venturi pipe 182 opens at both ends inside the cooling air introduction section 150. The venturi pipe 182 has an inflow portion 181 and an outflow portion 185 having relatively large inner diameters in the vicinity of the end portions. Further, the venturi pipe 182 has a small diameter portion 183 having a relatively small inner diameter between the inflow portion 181 and the outflow portion 185. The inflow portion 181, the small diameter portion 183, and the outflow portion 185 communicate with each other in this order. One end of the introduction pipe 184 communicates with the inside of the circulating duct 172 and the other end thereof communicates with the inside of the small diameter part 183 of the venturi pipe 182.

  Inside the cooling air introduction section 150, an airflow is always generated in which the cooling air supplied from the underfloor duct 113 to the cooling air introduction section 150 flows directly upward above the grating section 116. Therefore, when the aspirator 180 is disposed in the vicinity of the grating portion 116, the cooling air constantly flows into the inflow portion 181.

  The cooling air that has flowed into the inflow portion 181 reaches the narrow diameter portion 183 and increases the flow velocity. Thereby, the inside of the small diameter part 183 becomes a low pressure, and the inside of the circulating duct 172 is sucked through the introduction pipe 184. Thereby, the cooling air inside the circulating duct 172 is sucked out into the venturi pipe 182.

  The cooling air sucked out from the reflux duct 172 into the venturi pipe 182 is discharged from the outflow portion 185 of the venturi pipe 182 to the cooling air introduction portion 150. Thus, the cooling air discharged from the pressure adjusting vent 160 to the circulating duct 172 is returned to the cooling air introduction unit 150 again. Further, as long as the cooling air is ejected from the grating portion 116, the small diameter portion 183 of the venturi pipe 182 has a low pressure, so that the cooling air does not flow back to the circulating duct 172 through the introduction pipe 184.

  Thus, the circulation part 170 provided with the aspirator 180 has a function of circulating the cooling air discharged by pressure regulation without being supplied with electric power or the like from the outside. Therefore, it can be installed more easily without considering the supply of electric power.

  As mentioned above, although this invention was demonstrated using embodiment, the technical scope of this invention is not limited to the range as described in the said embodiment. It will be apparent to those skilled in the art that various modifications or improvements can be added to the above-described embodiment. It is apparent from the scope of the claims that the embodiments added with such changes or improvements can be included in the technical scope of the present invention.

  The order of operations in the devices shown in the claims, the description, and the drawings may be realized in any order, unless otherwise specified, and unless the order of operations interferes with the operation itself. . For the sake of convenience, even though “first”, “next”, and the like are described in the specification, the description does not limit the order.

DESCRIPTION OF SYMBOLS 100 Accommodation equipment, 102 Cold aisle, 104 Hot aisle, 110 Accommodation chamber, 112 Slab, 113 Underfloor duct, 114 Floating floor, 116 Grating part, 118 Vent hole, 120 Air conditioning apparatus, 122 Recovery part, 124 Outside air introduction part, 130 Rack body, 140 case, 142 exhaust fan, 144 front panel, 146 blade server, 148 blank panel, 150 cooling air inlet, 152 top cover, 154 door, 160 pressure adjusting vent, 162 opening, 164 hinge, 166 flap, 170 Reflux part, 172 Reflux duct, 174 Axial fan, 176 Check valve, 178 Thermal insulation, 180 Aspirator, 181 Inflow part, 182 Venturi pipe, 183 Small diameter part, 184 Inlet pipe, 185 Outlet part

Claims (7)

A rack body for housing information processing equipment having an exhaust fan;
An introduction unit that seals the cooling air supplied from the cooling air supply unit and introduces it into the front surface of the rack body;
A discharge portion in which a part of the cooling air to discharge exhaust gas discharged by the exhaust fan is introduced to the rack body, to the outside from the rear of the rack body,
A pressure adjusting unit that adjusts a total pressure of the cooling air introduced into the rack body by discharging a part of the cooling air supplied to the introduction unit that is not used for the cooling;
A rack comprising: a circulating portion that mixes the cooling air discharged from the pressure adjusting portion with the air cooled by the cooling air supply portion without passing through the cooling air supply portion, and circulates the air to the introduction portion.   2. The rack according to claim 1, wherein the circulating portion includes a pump that pushes the cooling air discharged from the pressure adjusting portion toward the introduction portion.   The rack according to claim 1 or 2, wherein the circulation part has a circulation channel that passes through the inside of the introduction part and circulates the cooling air on the upstream side of the introduction part.   The rack according to any one of claims 1 to 3, wherein the pressure adjusting unit is housed in a housing portion in which an information processing device is not housed among a plurality of housing portions provided in the rack body. . Any one of Claim 1 to Claim 4 in which the said circulation part contains the circulation duct which has a heat insulating material which an end is connected to the said introduction part via the said pressure adjustment part, and insulates the cooling air which circulates through the said circulation part. The rack according to item 1. A rack body for housing information processing equipment having an exhaust fan;
A cooling air supply unit for supplying cooling air;
An introduction part that seals the cooling air supplied from the cooling air supply part and introduces it into the front surface of the rack body;
A discharge portion in which a part of the cooling air to discharge the cooling air discharged by the exhaust fan is introduced to the rack body, to the outside from the rear of the rack body,
A pressure adjusting unit that limits an increase in the total pressure of the cooling air introduced into the rack body by discharging a part of the cooling air supplied to the introducing unit that is not used for the cooling from the introducing unit; ,
An information processing device comprising: a recirculation unit that mixes the cooling air discharged from the pressure adjusting unit with the air cooled by the cooling air supply unit without circulating the cooling air supply unit and causes the air to recirculate to the introduction unit Containment facilities.   The information processing equipment accommodation facility according to claim 6, wherein the cooling air supply unit supplies cooling air including air.

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