JP4742130B2 - Air volume management server and air volume management method - Google Patents

Description

  The present invention relates to an air volume management server and an air volume management method for managing an air volume discharged or supplied from equipment accommodated in an equipment room.

Conventionally, in an equipment room such as a server room where communication devices such as routers and information processing devices such as servers are collectively accommodated, air conditioning equipment for cooling exhaust heat from each of the installed information processing devices is installed. The Here, first, when designing the operation of the equipment room, the amount of exhaust heat and power consumption of the information processing apparatus to be installed in the future is predicted based on the installation area, the number of storage racks, and the like. Further, according to the prediction of the amount of exhaust heat from the information processing apparatus, the amount of cold air heat and the amount of cold air with the maximum allowance are designed, and the air conditioning equipment according to the design is installed. Similarly, when an information processing device is added, the amount of cold air heat or the amount of cold air corresponding to the added information processing device is predicted, and the air conditioning equipment is added.
Here, regarding the amount of cool air heat supplied from the air conditioner, the increase or decrease in the output of the air conditioner is controlled according to the heat load generated by the electrical equipment by measuring the temperature state around the air conditioner and in the equipment room. Is common. On the other hand, with regard to the amount of cool air from the air conditioner, it is difficult to grasp in real time the amount of air required by the electrical equipment, so the air conditioner blower output is set at a certain level so that it does not fall below the maximum air volume expected at the time of the above design. It is common to operate at a fixed value or more.
If the airflow from the air conditioner falls below the required airflow of the electrical equipment (that is, the airflow of the blower installed in the electrical equipment), an unintended air flow failure such as a short circuit of the exhaust heat air from the electrical equipment in the equipment room Even if the amount of cold air heat is sufficient, the temperature around the electric device may rise rapidly locally, which is not preferable.
Patent Document 1 proposes a technology in which the function of an SNMP (Simple Network Management Protocol) client is installed in such an information processing apparatus and air conditioning equipment, and these facilities are monitored and controlled in an integrated manner.
JP 2006-64254 A

However, the supply air volume set based on the above-mentioned prediction at the time of operation design is designed to allow excessive margins, resulting in energy loss due to excessive supply, or conversely, the predicted supply air volume is insufficient. It is possible to do. In particular, electrical equipment may actually be operated at a lower operating rate than expected at the time of design, and energy loss may be a problem.
Therefore, it is conceivable to measure the discharge air volume of the information processing equipment and the supply air volume of the air conditioning equipment over time after the start of operation, and redesign the optimal supply air volume. It took a lot of effort to grasp the situation. In particular, when planning to increase the number of information processing equipment and air conditioning equipment installed in the equipment room, close information sharing between the information processing equipment planner and the air conditioning equipment planner is necessary. However, there was no method for comparing and examining the capacity of the information processing apparatus and the capacity of the air conditioning equipment quantitatively and efficiently. For this reason, it takes a lot of human and time costs to expand the information processing equipment and the accompanying air conditioning equipment, and it is difficult to regularly measure the operating status of the equipment. In some cases, the design may vary due to judgment based on intuition.

  The present invention has been made in view of such a situation, and ascertains the relationship between the discharge air volume of the information processing apparatus of the equipment installed in the equipment room and the supply air volume of the air conditioning equipment in an integrated manner. An object of the present invention is to provide an air volume management server and an air volume management method capable of determining a suitable and appropriate supply air volume.

  In addition, the present invention supplies an electric device in which a blower for exhausting heat generated as exhaust gas is stored in an equipment room and operating in response to power supply, and cold air for processing the exhaust heat. An air volume management server equipped with an output unit that collects air volume information with air conditioning equipment and outputs the information, air volume information indicating the exhaust air volume for each electrical device housed in the equipment room, and cold air volume for each air conditioning equipment The air volume information storage unit for storing the air volume information indicating the air volume information, the air volume information indicating the exhaust air volume for each electrical device accommodated in the equipment room, and the air volume information indicating the cool air volume for each air conditioner are collected. An air volume information collecting unit to be stored in the storage unit, a predetermined specific space in the equipment room, an electrical device that discharges air as exhaust from the specific space, an air conditioning facility that discharges air as cold air from the specific space, and a specific space Empty as exhaust An electrical device that supplies air and an air conditioning facility that supplies air as cold air to the specific space, a spatial information storage unit that stores information that associates in advance, and an electrical device and an air conditioning facility that are associated with the specific space for each specific space A comparison diagram generating unit that generates a comparison diagram of the sum of the exhaust air volume information by the sum of the supply air amount information from the electrical equipment and air conditioning equipment associated with the specific space and outputs the comparison diagram to the output unit; It is characterized by providing.

  In addition, the present invention provides position information indicating each position in an equipment room in which an electrical device and an air conditioning facility are installed, and wind direction information indicating each wind direction of air discharged from the electrical device and air supplied from the air conditioning facility. And an air volume map illustrating the relative positional relationship between the electrical equipment and the air conditioning equipment in a two-dimensional diagram according to the position information stored in the position information storage unit. It further includes an air volume map generation unit that generates and outputs the air volume information and the wind direction information to the output unit at the positions of the electrical equipment and the air conditioning equipment in the air volume map.

In addition, the present invention calculates and compares the total value of the exhaust air volume by the electrical equipment in the specific space and the total value of the cool air volume by the air conditioning equipment in the specific space for each specific space , sum of exhaust air volume by the device is greater by more than a predetermined threshold than sum of cold air amount by the air-conditioning equipment, and instructs the air conditioning equipment to increase the cold air volume of the air-conditioning equipment, If the combined value of the cool air flow rate by the air conditioning equipment is greater than a predetermined threshold value than the sum of the exhaust air flow rates by the electrical equipment, the air conditioning facility is instructed to reduce the cool air flow rate of the air conditioning facility. And an air conditioning control unit.

  Further, the present invention stores air volume information indicating an exhaust air volume for each electrical device that discharges air when housed in an equipment room and operating, and air volume information indicating an air supply capacity of an air conditioner that supplies air to the equipment room. Information that associates the air volume information storage unit, the predetermined specific space in the equipment room, the electrical equipment that discharges air into the specific space, and the air conditioning equipment that supplies air to the specific space. An air volume management method using an air volume management server including a storage unit and an output unit for outputting information, wherein the air volume information collection unit includes an air volume information indicating an exhaust air volume for each electrical device housed in the equipment room, and an air conditioner Collecting the air volume information indicating the supplied air volume for each and storing the air volume information in the air volume information storage unit, and the comparison diagram generating unit for each specific space stored in the spatial information storage unit Wind corresponding to the equipment Generate a comparison diagram of the sum of the air volume information stored in the information storage unit and the sum of the air volume information stored in the air volume information storage unit corresponding to the air conditioning equipment associated with the specific space, and output the unit And a step of outputting to the device.

Further, according to the present invention, the air conditioning control unit calculates, for each specific space, a total value of the exhaust air volume by the electrical device in the specific space and a total value of the cool air volume by the air conditioning equipment in the specific space. In comparison, if the total value of the airflow exhausted by the electrical equipment is greater than a predetermined threshold value than the total value of the cool airflow by the air- conditioning equipment , the air- conditioning is performed so as to increase the supply airflow of the air-conditioning equipment. If the total value of the cool air volume by the air conditioning equipment is greater than a predetermined threshold value than the total value of the exhaust air volume by the electrical equipment, the cold air volume of the air conditioning equipment is decreased. And a step of instructing the air conditioning equipment .

  As described above, according to the present invention, the air volume management server includes a predetermined specific space in the facility room to be managed, an electrical device that exhausts air to the specific space, and an air conditioning facility that supplies cold air to the specific space. Is stored in advance, and the air volume information of the exhaust air volume for each electrical device and the cool air volume for each air conditioning facility is collected to correspond to the electrical device associated with the specific space for each specific space. Since the comparison of the sum of the airflow information and the sum of the airflow information of the air conditioning equipment corresponding to the specific space is generated and output, the airflow information and air conditioning of the electrical equipment installed in the equipment room are output. It is possible to output a comparative chart that integrally shows the relationship with the air volume information of the facility. Thereby, the manager of the equipment room can expect to efficiently determine whether or not the amount of cool air flow by the air conditioning equipment with respect to the amount of exhaust air flow of the electrical equipment installed in the equipment room is appropriate.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a block diagram showing the configuration of an air volume management system 1 according to the first embodiment of the present invention. The air volume management system 1 includes a plurality of information processing devices 20 (an information processing device 20-1, an information processing device 20-2, an information processing device 20-3,...) Installed in an equipment room, and an information processing device 20. A plurality of cooling equipment 30 (cooling equipment 30-1, cooling equipment 30-2, cooling equipment 3030,...) For cooling the exhaust heat from the information processing equipment 20, and an information processing equipment manager 60 connected to the information processing equipment 20. An incidental equipment manager 70 and an air volume management server 100 are provided.

  The information processing device 20 is a computer device that is housed in an equipment room and is equipped with a blower for exhausting heat generated as exhaust gas that is generated when operating in response to power supply. The cooling facility 30 is an air conditioning facility that is accommodated in the facility room and supplies cold air for processing exhaust heat from the information processing apparatus 20. FIG. 2 shows an example of the equipment room 10 in which the information processing apparatus 20 and the cooling equipment 30 are installed. For example, the equipment room 10 is provided with six racks of racks that accommodate the information processing devices 20 (rack racks 50-1, rack racks 50-2,... Rack racks 50-6. ). For example, nine racks are arranged in each rack rack 50. Position information for identifying the position is assigned in advance to each rack installation position, and in the example of the equipment room 10, the racks in the rack rack 50-1 are A1 to A9 and the rack rack 50-2 is in a rack. The position information of B10 to B18 is given to the racks of A10 to 18, rack rack 50-3, B1 to B9, and rack rack 50-4.

  Information processing apparatuses 20-1 to 20-6 are accommodated in the rack rack 50-1. Here, the rack of rack racks 50 is a rack having a plurality of slots, and a plurality of information processing apparatuses 20 may be accommodated. However, for convenience of explanation of the present embodiment, one information processing apparatus 20 is provided in each rack. Will be described as being housed. Similarly, information processing apparatuses 20-7 to 20-13 are accommodated in the rack rack 50-2. Information processing apparatuses 20-14 to 20-19 are accommodated in the rack rack 50-3. Information processing apparatuses 20-20 to 20-26 are accommodated in the rack rack 50-4.

  Here, the cooling equipment 30 is appropriately installed between the information processing apparatuses 20 accommodated in the racks of the rack stack 50. A3 and A7 in the rack rack 50-1, A12 and A16 in the rack rack 50-2, B3 and B7 in the rack rack 50-3, and B12 and B16 in the rack rack 50-4 are respectively included in the cooling facility 30. -2, cooling equipment 30-3, cooling equipment 30-4, cooling equipment 30-5, cooling equipment 30-7, cooling equipment 30-8, cooling equipment 30-9, and cooling equipment 30-10 are installed. Further, the cooling facility 30-1 is installed at the position A19, and the cooling facility 30-6 is installed at the position B19.

  In the equipment room 10, a space of an aisle formed by the rack rack 50-1 and the rack rack 50-2 is Aisle, and Aisle is a specific space for measuring the air volume by the air volume management system 1. To do. Similarly, the space of the passage (isle) formed by the rack mount 50-3 and the rack mount 50-4 is defined as isle B, and isle B is defined as a specific space for measuring the air volume by the air volume management system 1. Further, a space combining the isle A and the isle B is defined as zone A, and the zone A is defined as a specific space for measuring the air volume by the air volume management system 1.

Each of the information processing apparatus 20 and the cooling facility 30 has the function of an SNMP client, and transmits its own real-time air volume information to each in response to an inquiry based on SNMP. For example, when receiving an inquiry based on SNMP, the information processing apparatus 20 measures the air volume information indicating its own exhaust air volume at that time, and transmits the measured air volume information to the SNMP inquiry source. Here, the air volume information includes, for example, “m ³ / min” (cubic meters / minute) indicating the volume of air discharged per minute, “CFM” (cubic feet per minute) (cubic feet / minute), and the like. Expressed as a unit value. In the present embodiment, description will be made assuming that the unit of “m ³ / min” is used. When receiving the inquiry based on SNMP, the cooling facility 30 measures the air volume information (m ³ / min) indicating its own cold air volume at that time, and transmits the measured air volume information to the SNMP inquiry source. In addition, when the information processing apparatus 20 does not have a function of responding to the airflow information in response to the SNMP inquiry, the information processing apparatus 20 has a function of responding to its own power consumption at that time in response to the SNMP inquiry. .

Returning to FIG. 1, the information processing device manager 60 is connected to each of the plurality of information processing devices 20 via a network, transmits an inquiry based on SNMP to an SNMP client included in the information processing device 20, and performs communication. The information processing apparatus 20 has a function of an SNMP manager that collects real-time air volume information.
The incidental facility manager 70 is connected to each of the plurality of information processing devices 20 via a network, transmits an inquiry based on SNMP to an SNMP client included in the cooling facility 30 and performs communication, and performs real-time processing of the plurality of cooling facilities 30. An SNMP manager function for collecting air volume information is provided.

  The air volume management server 100 is a computer device that outputs a comparison diagram that integrally shows the relationship between the exhaust air volume of the information processing device 20 installed in a specific space of the facility room 10 to be managed and the cool air volume of the cooling facility 30. Yes, the air volume information collection unit 101, the power consumption information collection unit 102, the air volume information calculation unit 103, the air volume information storage unit 104, the spatial information storage unit 105, the position information storage unit 106, and the comparison diagram generation unit 107. An air volume map generation unit 108, an output unit 109, an excessive discharge determination unit 110, an excessive supply determination unit 111, and an air conditioning control unit 112.

  The air volume information collection unit 101 receives real-time air volume information of the exhaust air volume of the information processing apparatus 20 collected by the information processing apparatus manager 60 and the cold air volume of the cooling equipment 30 collected by the incidental equipment manager 70, and stores the air volume information. Store in the unit 104. Here, the operation value collection unit 101 collects operation values of each facility periodically, for example, every day, and stores them in the operation value storage unit 102 in association with the acquisition date and time.

  When the information processing apparatus 20 connected via the network does not have a function of transmitting air volume information in response to an inquiry based on SNMP, the power consumption information collection unit 102 responds only to power consumption. Communication based on the information processing apparatus 20 and SNMP is performed to acquire the power consumption of the information processing apparatus 20.

  The air volume information calculation unit 103 approximates and calculates the air volume information according to the power consumption of the information processing apparatus 20 acquired by the power consumption information collection unit 102. For example, the air volume information calculation unit 103 acquires power consumption from the information processing apparatus 20 and calculates a value of ((Σpower consumption n) / ΔT) as air volume information. Here, the power consumption n is each value of the plurality of power consumptions acquired from the information processing apparatus 20 within a certain time. ΔT is a difference between the exhaust temperature and the intake air temperature of the specific space (exhaust temperature−intake air temperature). Here, ΔT is a value that is not measured for each information processing device 20 included in the specific space, and is predetermined according to the situation of the equipment room 10 between 8 ° C. and 15 ° C. or the like.

  The air volume information calculation unit 103 may calculate the value of (Σ (power consumption n / ΔTn)) as the air volume information. Here, ΔTn is measured, for example, by measuring the exhaust temperature and the intake air temperature of the information processing apparatus 20 when the power consumption information collecting unit 102 makes an SNMP inquiry, and the difference between the measured exhaust gas temperature and the intake air temperature is calculated. This is the value shown. In addition, the air volume information calculation unit 103 stores in advance a data table in which the exhaust air volume corresponding to the power consumption is associated based on the device characteristics of the information processing device 20, and acquires and reads the exhaust air volume corresponding to the power consumption. The air volume information may be used.

  The air volume information storage unit 104 stores air volume information indicating the exhaust air volume for each information processing device 20 accommodated in the facility room 10 and air volume information indicating the cool air volume for each cooling facility 30. FIG. 3 is a diagram illustrating a data example of the air volume information stored in the air volume information storage unit 104. As shown in FIG. 3, the air volume information storage unit 104 stores the air volume information collected by the air volume information collection unit 101 or the air volume information calculated by the air volume information calculation unit 103 in association with the equipment name. . The facility name is information for identifying the information processing apparatus 20 or the cooling facility 30. The air volume information is air volume information indicating the exhaust air volume of the information processing apparatus 20 or the supply air volume of the cooling facility 30.

  The space information storage unit 105 is a space that associates a predetermined space in the facility room 10 with an information processing device 20 that discharges air into the space and a cooling facility 30 that supplies air to the space. Information is stored in advance. For example, FIG. 4 is a diagram illustrating an example of spatial information data stored in the spatial information storage unit 105. The spatial information storage unit 105 stores identification information of the information processing device 20 and identification information of the cooling facility 30 in association with information for identifying the specific space. In the example of FIG. 4, in the specific space “Aisle A”, the 13 information processing devices 20 from the information processing device 20-1 to the information processing device 20-13 and the cooling facilities 30-1 to 30-5 are included. Five cooling facilities 30 are associated with each other. Such spatial information is designed and determined in advance by an administrator in accordance with the installation positions of the information processing apparatus 20 and the cooling equipment 30 in the equipment room 10 as shown in FIG.

  Returning to FIG. 1, the position information storage unit 106 includes position information indicating respective positions in the facility room 10 in which the information processing device 20 and the cooling facility 30 are installed, air discharged from the information processing device 20, and the cooling facility. The wind direction information indicating each wind direction with the air supplied from 30 is stored in association with each other. FIG. 5 is a diagram illustrating an example of data stored in the position information storage unit 106. In the position information storage unit 106, an equipment name, position information, and wind direction information are stored in association with each other. The facility name is information for identifying the information processing apparatus 20 or the cooling facility 30. The position information is information indicating a position where the corresponding information processing device 20 or the cooling facility 30 is installed in the facility room 10. For example, the position information is identification information given in advance so as to identify each installation position in the facility room 10 as shown in FIG. The wind direction information is information indicating the wind direction according to the air discharge port from the corresponding information processing device 20 or the cooling facility 30. For example, the wind direction is represented by an arrow symbol such as “←” if the wind direction is left, or “→” if the wind direction is right on a predetermined map. For example, an upward balloon that discharges air upward is performed. When the information processing apparatus 20 or the cooling facility 30 is present, the wind direction is indicated by characters such as “up”.

  For each specific space stored in the spatial information storage unit 105, the comparison diagram generation unit 107 adds the airflow information stored in the airflow information storage unit 104 corresponding to the information processing device 20 associated with the specific space. And a comparison diagram of the combined value of the air volume information stored in the air volume information storage unit 104 corresponding to the cooling facility 30 associated with the same specific space is generated and output to the output unit 109. For example, FIG. 6 is a comparison diagram for aisle A generated by the comparison diagram generation unit 107 based on the air volume information shown in FIG. 3 and the spatial information shown in FIG. The comparison diagram generation unit 107 reads the identification information of the information processing apparatus 20 and the identification information of the cooling facility 30 corresponding to the specific space that is the target of comparison diagram generation from the spatial information storage unit 105. The comparison diagram generation unit 107 stores the total value of the air volume information corresponding to the information processing apparatus 20 read from the spatial information storage unit 105 and the total value of the air volume information of the cooling facility 30 in the air volume information storage unit 104. The air volume information is read and calculated. In this example, the total value of the air volume information of 13 units from the information processing device 20-1 to the information processing device 20-13 corresponding to the isle A is 325. On the other hand, the total value of the air volume information of the five units 30-1 to 30-5 corresponding to the isle A is 445. The comparison chart generation unit 107 is a comparison chart in which the total value of the air volume information of the information processing device 20 is represented by a bar graph, with the exhaust air volume of the specific space being used and the sum of the air volume information of the cooling facility 30 being the cold air volume of the specific space. Is generated and output to the output unit 109. Similarly, FIG. 7 is a diagram illustrating an example of a comparison diagram for the specific space aisle B generated by the comparison diagram generation unit 107. Similarly, FIG. 8 is a diagram illustrating an example of a comparison diagram for the specific space zone A generated by the comparison diagram generation unit 107.

  9 and 10 are diagrams showing comparative diagrams generated by the comparative diagram generating unit 107 in consideration of the wind direction information stored in the position information storage unit 106. FIG. FIG. 9 is a bar graph showing air (in) (supply air volume) toward the inside of the specific space aisle A and air (out) (exhaust air volume) toward the outside of the specific space aisle A. Here, the exhaust discharged from the information processing apparatus 20 is indicated by diagonal lines, and the cold air discharged from the cooling facility 30 is indicated by dots. For example, the exhaust gas is colored in red so that the cool air is indicated in blue. You may make it show. FIG. 10 is a diagram showing a comparison diagram of the air volume of the specific space aisle B similarly generated in consideration of the wind direction.

  Returning to FIG. 1, the air volume map generation unit 108 shows the relative positional relationship between the information processing apparatus 20 and the cooling facility 30 in a two-dimensional view according to the position information stored in the position information storage unit 106. A map is generated, and air volume information and air direction information are illustrated and output to the output unit 109 at the positions of the information processing device 20 and the cooling facility 30 in the generated air volume map. For example, FIG. 11 is a diagram illustrating an example of an air volume map generated by the air volume map generation unit 108 for the specific space aisle A. Here, the air volume in the specific space is indicated by the direction of the arrow, the arrow pattern, and the air volume information. Here, the direction of the arrow represents the wind direction. In the arrow pattern, the exhaust discharged from the information processing apparatus 20 is indicated by diagonal lines, and the cool air discharged from the cooling facility 30 is indicated by dots. At each position where the information processing apparatus 20 or the cooling facility 30 is installed, the value of the air volume information is shown. Here, the information processing apparatus 20-10 arranged in the position information A14 performs an upper balloon, and the upper balloon is represented by a symbol “◯”. Here, exhaust and cold are distinguished from each other by an arrow pattern. However, for example, the exhaust may be indicated by red and the cool air may be indicated by blue. Further, the air volume map generation unit 108 may generate an air volume map indicating the air volume based on the air volume information and the position where the air volume information is illustrated. In this case, the air volume map generation unit 108 generates an air volume map as shown in FIG.

The output unit 109 is a display that displays and outputs the comparison map generated by the comparison map generation unit 107 and the comparison map generated by the air volume map generation unit 108.
The excessive discharge determination unit 110 calculates and compares the sum of the exhaust air volume of the information processing apparatus 20 and the sum of the cool air air volume of the cooling facility 30 for each specific space, and compares the sum of the exhaust air volume of the information processing apparatus 20. However, when it exceeds the predetermined threshold value and exceeds the total value of the cool air flow rate of the cooling facility 30, a warning for increasing the supply air flow rate of the cooling facility 30 is output. Here, it is assumed that the “predetermined threshold value” is 0, and a warning may be issued when the combined value of the exhaust air volume exceeds the combined value of the cool air volume. The warning output by the excessive discharge determination unit 110 may be output to the output unit 109 as character string information, or may be output to the incidental facility manager 70, for example.

  The excessive supply determination unit 111 compares the total value of the exhaust air volume of the information processing device 20 with the total value of the cold air volume of the cooling facility 30 for each specific space, and the total value of the cold air volume of the cooling facility 30 is If the total value of the exhaust amount of the device 20 is greater than a predetermined threshold value, a warning for reducing the supply air amount of the cooling facility 30 is output. Here, when the total value of the cool air volume exceeds the total value of the exhaust air volume of the information processing device 20, sufficient cool air is supplied to cool the exhaust heat from the information processing device 20. It is thought that there is. However, when the total value of the cool air flow volume exceeds the total value of the exhaust air volume of the information processing device 20 and energy loss occurs, the supply cool air is reduced to an appropriate level to improve the energy efficiency. It is desirable. Accordingly, the excessive supply determination unit 111 outputs a warning when the total value of the cool air flow rate of the cooling facility 30 is larger than a predetermined threshold value than the total value of the exhaust air flow rate of the information processing device 20. The warning output by the oversupply determination unit 111 may be output to the output unit 109 as character string information, or may be output to the incidental facility manager 70, for example. In this case, the incidental facility manager 70 that has received the warning may control the cooling facility 30 in accordance with the received warning to reduce the cool air supplied by the cooling facility 30.

  The air conditioning control unit 112 calculates and compares the total value of the air volume information of the information processing device 20 and the total value of the air volume information of the cooling facility 30 for each specific space, and compares the total value of the air volume information of the information processing device 20. When the air flow rate information of the cooling facility 30 is larger than a predetermined threshold value, the instruction information is transmitted to the cooling facility 30 to increase the cool air flow rate. In addition, the air conditioning control unit 112 compares the total value of the air volume information of the information processing device 20 and the total value of the air volume information of the cooling facility 30 for each specific space, and the total value of the air volume information of the cooling facility 30 is the information When it exceeds the predetermined threshold value and is larger than the total value of the air volume information of the processing device 20, information instructing the cooling facility 30 to reduce the cool air volume is transmitted. If it does in this way, operation control of cooling equipment 30 can be performed according to the air volume information collected by air volume management server 100, and the energy loss by excessive supply can be prevented. Here, the air conditioning control unit 112 may perform the determination process by itself, but increases or decreases the amount of cool air flow of the cooling facility 30 based on the determination result by the excessive discharge determination unit 110 or the excessive supply determination unit 111. Information for instructing may be transmitted.

  Next, an operation example will be described in which the air volume management server 100 according to the present invention outputs a comparison diagram that integrally shows the relationship between the power consumption of the information processing apparatus of the facility installed in the facility room and the capacity of the incidental facility. FIG. 16 is a diagram illustrating an operation example of the air volume management server 100. First, the air volume information collection unit 101 communicates with the information processing device manager 60 and the incidental equipment manager 70 to collect air volume information and store it in the air volume information storage unit 104 (step S1). At this time, if there is an information processing apparatus 20 that cannot acquire the air volume information by the air volume information collection unit 101, the power consumption information collection unit 102 acquires the power consumption of the information processing apparatus 20, and obtains the acquired power consumption. The air volume information calculation unit 103 calculates the corresponding air volume information and stores it in the air volume information storage unit 104.

  The comparison diagram generation unit 107 generates a comparison diagram of the air volume information based on the air volume information and the spatial information stored in the air volume information storage unit 104 and the spatial information storage unit 105 (step S2). Also, the air volume map generation unit 108 is based on the air volume information stored in the air volume information storage unit 104, the spatial information stored in the spatial information storage unit 105, and the position information stored in the position information storage unit 106. Is generated (step S3). Further, the excessive discharge determination unit 110 calculates and compares the total value of the exhaust air volume of the information processing device 20 and the total value of the supply air amount of the cooling facility 30 for each specific space, and compares the exhaust air volume of the information processing device 20 When the total value is larger than a predetermined threshold value than the total value of the supply air volume of the cooling facility 30, a warning for increasing the supply air volume of the cooling facility 30 is output (step S4). And the excessive supply determination part 111 compares the total value of the discharge air volume of the information processing apparatus 20 with the total value of the supply air volume of the cooling facility 30 for each specific space, and the total value of the supply air volume of the cooling facility 30 is When it exceeds the predetermined threshold value than the total value of the exhausted air volume of the information processing device 20, a warning for reducing the supplied air volume of the cooling facility 30 is output (step S5). The output unit 109 outputs the comparison diagram generated by the comparison diagram generation unit 107 and the air volume map generated by the air volume map generation unit 108. The output unit 109 outputs a warning when a warning is output from the excessive discharge determination unit 110 or the excessive supply determination unit 111 (step S6).

  In the air volume management system 1 according to the above-described embodiment, for example, the air volume information collection unit 101 periodically operates other function units according to a process of periodically collecting operating values every day. An air volume map and a warning may be output. Alternatively, only the operation of step S1 may be performed periodically, and the processing from step S2 to step S6 may be performed according to an instruction input from the management user of the air volume management server 100.

  In the present embodiment, the information processing apparatus 20 has been described as an example of an electrical device installed in the facility room 10, but a blower for exhausting heat generated as exhaust gas when operating in response to power feeding is used. Any electrical device other than the information processing device 20 may be applied as long as the electrical device is mounted.

  Further, in the present embodiment, a comparison diagram between the exhausted air volume and the supplied air volume in the specific space as shown in FIGS. 9 and 10 is generated based on the wind direction information stored in the position information storage unit 106. However, the spatial information storage unit 105 stores the exhaust air volume and the supply air volume of the information processing device 20 and the cooling facility 30 in association with each other, and based on the information stored in the spatial information storage unit 105, You may make it produce | generate the comparison figure with supply air volume. In this case, the space information storage unit 105 includes the specific space, the information processing device 20 that discharges air as exhaust from the specific space, the cooling facility 30 that discharges air as cold air from the specific space, and the air as exhaust into the specific space. Information for associating the information processing apparatus 20 to be supplied and the cooling facility 30 for supplying air as cold air to the specific space is stored in advance. And the comparison figure production | generation part 107 from the information processing apparatus 20 matched with the specific space, the total value of the discharge | emission air volume information by the cooling equipment 30, and the information processing equipment 20 matched with the specific space, and the cooling equipment 30 from A comparison diagram with the total value of the supply air volume information is generated and output to the output unit 109.

  Note that a program for realizing the function of the processing unit in the present invention is recorded on a computer-readable recording medium, and the program recorded on the recording medium is read into a computer system and executed to execute an air volume in a specific space. Management may be performed. Here, the “computer system” includes an OS and hardware such as peripheral devices. The “computer system” includes a WWW system having a homepage providing environment (or display environment). The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. Further, the “computer-readable recording medium” refers to a volatile memory (RAM) in a computer system that becomes a server or a client when a program is transmitted via a network such as the Internet or a communication line such as a telephone line. In addition, those holding programs for a certain period of time are also included.

  The program may be transmitted from a computer system storing the program in a storage device or the like to another computer system via a transmission medium or by a transmission wave in the transmission medium. Here, the “transmission medium” for transmitting the program refers to a medium having a function of transmitting information, such as a network (communication network) such as the Internet or a communication line (communication line) such as a telephone line. The program may be for realizing a part of the functions described above. Furthermore, what can implement | achieve the function mentioned above in combination with the program already recorded on the computer system, and what is called a difference file (difference program) may be sufficient.

It is a block diagram which shows the structural example of the air volume management system by one Embodiment of this invention. It is a figure which shows the example of an outline | summary of the equipment room managed by the air volume management system by one Embodiment of this invention. It is a figure which shows the example of data memorize | stored in the air volume information storage part by one Embodiment of this invention. It is a figure which shows the example of data memorize | stored in the spatial information storage part by one Embodiment of this invention. It is a figure which shows the example of data memorize | stored in the positional infomation storage part by one Embodiment of this invention. It is a figure which shows the example of the comparison figure which the comparison figure production | generation part by one Embodiment of this invention produces | generates. It is a figure which shows the example of the comparison figure which the comparison figure production | generation part by one Embodiment of this invention produces | generates. It is a figure which shows the example of the comparison figure which the comparison figure production | generation part by one Embodiment of this invention produces | generates. It is a figure which shows the example of the comparison figure which the comparison figure production | generation part by one Embodiment of this invention produces | generates. It is a figure which shows the example of the comparison figure which the comparison figure production | generation part by one Embodiment of this invention produces | generates. It is a figure which shows the example of the comparison figure which the air volume map production | generation part by one Embodiment of this invention produces | generates. It is a figure which shows the example of the comparison figure which the air volume map production | generation part by one Embodiment of this invention produces | generates. It is a flowchart which shows the operation example of the air volume management system by one Embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Air volume management system 10 Equipment room 20 Information processing apparatus 30 Cooling equipment 50 Rack arrangement 60 Information processing apparatus manager 70 Attached equipment manager 100 Air volume management server 101 Air volume information collection part 102 Power consumption information collection part 103 Air volume information calculation part 104 Air volume information Storage unit 105 Spatial information storage unit 106 Position information storage unit 107 Comparison diagram generation unit 108 Air volume map generation unit 109 Output unit 110 Excessive discharge determination unit 111 Oversupply determination unit 112 Air conditioning control unit

Claims (5)

The amount of air flow between the electrical equipment that is installed in the equipment room and that is equipped with a blower that exhausts heat generated when exhausted when operating in response to power supply, and the air conditioning equipment that supplies cold air to process the exhaust heat An air volume management server including an output unit that collects information and outputs information,
An air volume information storage unit for storing air volume information indicating the exhaust air volume for each of the electrical devices housed in the facility room, and air volume information indicating the cool air volume for each of the air conditioning facilities;
An air volume information collection unit that collects air volume information indicating the exhaust air volume for each of the electrical equipment housed in the facility room and air volume information indicating a cold air volume for each of the air conditioning facilities, and stores the air volume information in the air volume information storage unit;
A predetermined specific space in the facility room, the electric device that discharges air as exhaust from the specific space, the air-conditioning facility that discharges air as cold air from the specific space, and supplies air as exhaust to the specific space A space information storage unit that stores in advance information that associates the electrical equipment and the air conditioning equipment that supplies air as cold air to the specific space;
For each specific space, the total value of the discharge air volume information by the electrical equipment and the air conditioning equipment associated with the specific space, and the supply air volume information from the electrical equipment and the air conditioning equipment associated with the specific space A comparison diagram generation unit that generates a comparison diagram with the sum of the values and outputs the comparison diagram to the output unit;
An air volume management server comprising: Position information indicating respective positions in the facility room in which the electrical equipment and the air conditioning equipment are installed, and wind direction information indicating respective wind directions of air discharged from the electrical equipment and air supplied from the air conditioning equipment; Is stored in association with the position information storage unit,
According to the position information stored in the position information storage unit, an air volume map illustrating a relative positional relationship between the electrical equipment and the air conditioning equipment in a two-dimensional view is generated, and the electrical equipment in the air volume map An air volume map generation unit that outputs the air volume information and the wind direction information to the output unit in a position with the air conditioning facility;
The air volume management server according to claim 1, further comprising: For each specific space, the total value of the exhaust air volume by the electrical device in the specific space and the total value of the cold air volume by the air conditioning equipment in the specific space are calculated and compared, and the total exhaust air volume by the electrical device is calculated. If the value is greater than a predetermined threshold value than the total value of the cool air flow rate by the air conditioning facility, the air conditioning facility is instructed to increase the cool air flow rate of the air conditioning facility, and the cool air flow rate by the air conditioning facility An air conditioning control unit that instructs the air conditioning equipment to reduce the amount of cool air flow of the air conditioning equipment, when the sum of the above is larger than a predetermined threshold value than the sum of the exhaust air volume by the electrical equipment ,
Further air volume management server according to any one of claims 1 or claim 2, characterized in that it comprises a. Air volume information storage for storing air volume information indicating the exhaust air volume for each electrical device that discharges air when housed in a facility room and operating, and air volume information indicating the supply air volume of an air conditioning facility that supplies air to the facility room Information for associating the unit, a predetermined specific space in the equipment room, the electrical device for discharging air into the specific space, and the air conditioning equipment for supplying air to the specific space An air volume management method by an air volume management server having a storage unit and an output unit for outputting information,
An air volume information collection unit collects air volume information indicating the discharge air volume for each of the electrical equipment accommodated in the equipment room and air volume information indicating the supply air volume for each of the air conditioning equipment, and stores them in the air volume information storage unit. Steps,
For each of the specific spaces stored in the spatial information storage unit, the comparison diagram generation unit adds the airflow information stored in the airflow information storage unit corresponding to the electrical device associated with the specific space. And a step of generating a comparison diagram of the sum of the airflow information stored in the airflow information storage unit corresponding to the air conditioning equipment associated with the specific space and outputting the comparison diagram to the output unit;
An air volume management method comprising: The air conditioning control unit calculates and compares the total value of the exhaust air volume by the electric device in the specific space and the total value of the cold air volume by the air conditioning facility in the specific space for each specific space , When the combined value of the exhaust air volume by the air conditioner is greater than a predetermined threshold value than the combined value of the cool air air volume by the air conditioning equipment, the air conditioning equipment is instructed to increase the supply air volume of the air conditioning equipment, When the total value of the cool air flow rate by the air conditioning equipment is greater than a predetermined threshold value than the total value of the exhaust air flow rate by the electrical equipment, the air conditioning facility is instructed to reduce the cool air flow rate of the air conditioning facility. Steps,
The air volume management method according to claim 4 , further comprising:

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