KR20200072765A - Evaluation method of air conditioning state for server room and evaluation system thereof - Google Patents

Abstract

The present invention relates to a method for evaluating an air conditioning condition in a server room and a system thereof capable of obtaining information on an optimal arrangement position of a server rack without actually placing a server rack in a server room. In detail, the present invention relates to the method for evaluating an air conditioning condition in a server room which includes the steps of: setting one or more server room data in a server room database unit in which a plurality of server room data is stored; setting one or more air conditioning data in an air conditioning database unit in which a plurality of air conditioning data is stored; setting one or more server rack data in a server rack database unit in which a plurality of server rack data is stored; simulation-disposing a server rack having the set server rack data in a server room having the set server room data; and calculating an air conditioning condition of the server room according to an arrangement position of the server rack through analysis of a top surface temperature inside the server room using CFD simulation.

Description

Method for evaluating air conditioning condition of server room and its evaluation system{EVALUATION METHOD OF AIR CONDITIONING STATE FOR SERVER ROOM AND EVALUATION SYSTEM THEREOF}

The present invention relates to a method for evaluating the air conditioning condition of a server room and an evaluation system thereof, and in detail, air conditioning in a server room capable of obtaining optimal placement information of a server rack without actually operating the server rack by placing the server rack in the server room. It relates to a state evaluation method and its evaluation system.

In general, a number of server racks are arranged in a plurality of columns and rows in a server room inside a data center.

Inside the server rack, the servers are arranged in a vertical direction while forming a layer, and each server rack is arranged in a horizontal direction to form a group.

When the server operates, high heat is generated. If the heat discharged from the server unit is not properly and quickly discharged to the outside, a heat load is applied to the server unit, causing a failure of the server unit.

To this end, an air conditioning control system such as a thermo-hygrostat is installed in the server room to cool the server, so that the inside of the server room can maintain a constant temperature range and humidity range.

Such a thermo-hygrostat is disclosed in Korean patent registration 10-1439507.

However, the server rack is placed in the server room, depending on the experience, or the location of the existing server rack, which is operating normally, is placed even when the structure of the server room or the specifications of the server rack are different. Contrary to expectations, hot spots and overcooling occur frequently in certain areas of the server room, leading to an increased risk of air conditioning or reduced air conditioning efficiency.

In particular, if the degree of hot spot or overcooling in the server room is severe, the server rack, which has already been installed, must be demolished or relocated, and thus the installation cost increases excessively and the working time increases.

Therefore, the object of the present invention is to solve the problems according to the prior art.

Specifically, an object of the present invention is to provide a method for evaluating the air conditioning condition of a server room and a system for evaluating the air conditioning state of the server room, which can obtain information on the optimal placement position of the server rack without actually operating the server rack in a server room.

Also, another object of the present invention is to simulate the airflow device according to the arrangement of the server rack by performing simulation through CFD (Computational Fluid Dynamics) analysis before actually placing the server rack in the closed room and/or the server room. It is to provide a method for evaluating an air conditioning condition in a server room and an evaluation system for evaluating air conditioning efficiency and air conditioning risk in operation and IT equipment.

In addition, another object of the present invention is a server room that can efficiently deploy the server rack so that the air conditioning state (eg, temperature and/or humidity) of the closed room and/or the server room is in an optimal operating state. It is to provide a method for evaluating air conditioning conditions and a system for evaluating it.

The method for evaluating the air conditioning state of a server room according to the present invention for solving the above-mentioned problems includes setting one or more server room data in a server room database unit in which a plurality of server room data are stored; Setting one or more air conditioning data in an air conditioning database unit in which a plurality of air conditioning data are stored; Setting one or more server rack data in a server rack database unit in which a plurality of server rack data are stored; Placing a server rack having the set server rack data in a server room having the set server room data; And calculating air conditioning state of the server room according to the arrangement position of the server rack through analysis of a top surface temperature inside the server room using CFD (Computational Fluid Dynamics) simulation.

In addition, preferably, it characterized in that it further comprises the step of outputting the air conditioning state of the server room to the output unit.

In addition, preferably, the air conditioning state of the server room is divided for each unit area of the server room, and the unit area of the server room is normal, hot spot, and over cooling. It is characterized in that one of the air conditioning conditions is selected.

In addition, preferably, the step of selecting the optimal placement position of the server rack while changing the arrangement position of the server rack inside the server room so that the air conditioning state of the unit area of the server room is all in a normal state. It is characterized by.

In addition, preferably, the air conditioning state of the server room is characterized in that it includes at least one of air conditioning efficiency and air conditioning risk.

In addition, preferably, the step of setting the server room data, the step of setting the air conditioning data, and the step of setting the server rack data may be performed in any order or at the same time.

In addition, preferably, the server room data is characterized in that it includes at least one of the data related to the structure, internal temperature, and internal humidity of the server room.

In addition, preferably, the air conditioning data includes data on power consumption of the air conditioning apparatus and data on temperature, humidity, wind speed, air flow, and air flow of air supplied from the air conditioning apparatus to the guide space of the server room. Characterized in that it comprises at least one of.

In addition, preferably, the server rack data is characterized in that it includes data related to the power consumption of the server rack.

In addition, preferably, the data related to the power consumption of the server rack and the upper surface temperature data in the server room provided when analyzing the upper surface temperature in the server room using the CFD simulation, the server room actually operated Characterized in that the data obtained from.

In addition, an air conditioning condition evaluation system of a server room according to the present invention for solving the above-described problems includes a server room database unit in which a plurality of server room data are stored; An air conditioning database unit storing a plurality of air conditioning data; A server rack database unit in which a plurality of server rack data are stored; A first input unit for inputting the server room data, the air conditioning data, and the server rack data selected by a user from the server room database unit, the air conditioning database unit, and the server rack database unit; A second input unit for inputting a placement position of the server rack having the server rack data selected by the user in a server room having the server room data selected by the user; A memory unit for storing upper surface temperature data in the server room; A simulator unit performing analysis of the upper surface temperature in the server room using CFD simulation based on the values input from the first input unit and the second input unit; And a control unit that calculates an air conditioning state of the server room by matching the upper surface temperature value in the server room acquired by the simulator unit with the upper surface temperature data in the server room stored in the memory unit. do.

In addition, preferably, it characterized in that it further comprises an output for outputting the air conditioning state of the server room.

In addition, preferably, the controller determines the air conditioning state of the server room to be one of a normal state, a hot spot state, and an overcooling state for each unit area of the server room. It is characterized by.

In addition, preferably, the control unit selects the optimal placement position of the server rack while changing the arrangement position of the server rack inside the server room so that the air conditioning state of the unit area of the server room is all normal. It is characterized by.

In addition, preferably, the upper surface temperature data inside the server room stored in the memory unit is characterized in that the data obtained from the server room actually operated.

According to the solution means of the above-described problem, the present invention can obtain the optimal placement position information of the server rack without actually operating it by placing the server rack in the server room, thereby reducing the installation cost and shortening the working time. .

In addition, according to the present invention, the air conditioning efficiency in the operation of the air conditioner and the operation of the IT equipment according to the arrangement of the server rack by simulation through CFD analysis before actually placing the server rack in the closed room and/or the server room. And the air conditioning risk.

In addition, according to the present invention, the server rack can be efficiently arranged such that the air conditioning state (eg, temperature and/or humidity) of the closed room and/or the server room is in an optimal operating state.

In addition, according to the present invention, energy consumed in air conditioning control of the closed room and/or the server room can be reduced.

1 is a state diagram showing the temperature distribution inside the server room,
2 is a schematic system diagram of an air conditioning control system in a server room according to an embodiment of the present invention,
3 is a schematic block diagram of an air conditioning condition evaluation system in a server room according to an embodiment of the present invention,
4 is a schematic flowchart of a method for evaluating an air conditioning condition in a server room according to a first embodiment of the present invention,
5 is a schematic flowchart of a method for evaluating an air conditioning condition in a server room according to a second embodiment of the present invention,
6 is a schematic diagram showing an air conditioning state for each unit area of a server room in the server room air conditioning state evaluation system according to an embodiment of the present invention.

Advantages and features of the present invention, and methods for achieving them will be clarified with reference to embodiments described below in detail together with the accompanying drawings.

However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only the embodiments allow the disclosure of the present invention to be complete, and are conventional in the art to which the present invention pertains. It is provided to fully inform the knowledgeable person of the scope of the invention, and the invention is only defined by the scope of the claims.

In addition, the terminology used herein is for describing the embodiments and is not intended to limit the present invention.

In the present specification, the singular form also includes the plural form unless otherwise specified in the phrase. As used herein, "comprises" and/or "comprising" does not exclude the presence or addition of other components than those mentioned.

Unless otherwise defined, all terms (including technical and scientific terms) used in the present specification may be used as meanings commonly understood by those skilled in the art to which the present invention pertains.

Hereinafter, the present invention will be described with reference to the accompanying drawings.

1 is a state diagram showing a temperature distribution inside a server room, and FIG. 2 is a schematic system diagram of an air conditioning control system in a server room according to an embodiment of the present invention.

1 and 2, in the server room, a plurality of server racks 100 form one row, and a plurality of server racks 100 are arranged to face each other apart.

More specifically, one server rack 100 column includes a plurality of server racks 100, and the plurality of server racks 100 are arranged such that side surfaces thereof are adjacent to each other.

In addition, the plurality of server rack 100 rows are arranged to be spaced apart from each other in the front-rear direction, and thus the spaces in which the server rack 100 rows are spaced apart in the front-rear direction form a cold aisle 200 or a hot aisle 300. .

Here, two rows of server racks 100 disposed adjacent to each other are arranged to face each other or to face each other.

Since the server generates a lot of heat due to the nature of the server, it is important to provide cooling air continuously so that the server temperature does not rise above a certain temperature in order to prevent problems caused by overheating of the server.

To this end, cooling air is supplied between a specific row of the server rack 100 and the adjacent row of the server rack 100, and the cold aisle 200 means a space to which the cooled air is supplied. In the cold aisle 200, the facing server racks 100 or the rows of the server rack 100 are arranged such that the front surface of which cooling air is supplied is opposed.

Alternatively, the thermal aisle 300 means a space in which heated air (ie, hot air) is released after cooling air supplied through the front of the server rack 100 exchanges heat with the server. In the thermal aisle 300, the server racks 100 or the server rack 100 rows are arranged so that the rear side where cooling air is exhausted is opposed.

The area indicated by ⓒ in FIG. 1 is cold aisle 200, and the portion indicated by ⓗ is a thermal aisle 300 where heat is exchanged with each server to release hot air. In FIG. 2, the blue arrow indicates cooling air to cool the server, and the red arrow indicates high temperature air after the server is cooled.

In addition, in order to increase the cooling efficiency and the concentration of cooling air, the closed room may be implemented such that the cold aisle 200 forms an enclosed space. To this end, a blocking part for blocking air flow between the cold aisle 200 and the thermal aisle 300 surrounding the server rack 100 is provided at an upper portion of each of the plurality of server racks 100. 210) is provided.

The blocking partition 210 may be configured to have a height-adjustable structure to improve height compatibility between the server rack 100 and the double ceiling.

Looking at the structural point of view, the air conditioning control system 1000 of the server room includes a closed room, guide space 400, exhaust duct 500 and/or double ceiling, cooling air supply control unit 600, air conditioning device ( Not shown), a sensing unit (not shown), and a control unit 2010.

The closed room includes a plurality of cold aisles 200, a plurality of hot aisles 300, and a plurality of server racks 100 disposed to be surrounded in the front-rear direction by the aisles 200 and the aisle 300. Includes.

The plurality of cold aisles 200 is provided between two opposite rows of the server rack 100 among the plurality of server racks 100 and is configured to flow cooling air to be introduced into the server rack 100.

The plurality of thermal aisles 300 are provided opposite the cold aisles 200 to surround the server rack 100 together with the cold aisles 200 and will be discharged after cooling the server rack 100. It is configured to flow hot air.

The guide space 400 is provided under a support floor (not shown) in which the sealed room is supported, and is configured to guide air to be introduced into the plurality of cold aisles 200.

The exhaust duct 500 and/or the double ceiling are configured such that the hot air discharged from the thermal corridor 300 converges to recover the hot air to the air conditioner.

The air conditioner is provided outside the sealed room and is configured to appropriately control the temperature and humidity of air to be introduced into the guide space 400 by exchanging the hot air with a refrigerant.

The plurality of sensing units are provided in each of the server racks 100 and sense air condition status information such as humidity and temperature and/or state information of each server rack 100 including power consumption of each server rack 100. It is configured to.

The control unit 2010 is configured to control the closed room, the guide space 400, the cooling air supply control unit 600, the air conditioning device, and the sensing unit, and is configured to be able to drive various control algorithms.

3 is a schematic block diagram of an air conditioning condition evaluation system in a server room according to an embodiment of the present invention.

From a control signal flow point of view, as shown in FIG. 3, the air conditioning state evaluation system 2000 of the server room according to an embodiment of the present invention includes a server room database unit 2010 and an air conditioning database unit 2020 , Server rack database unit 2030, memory unit 2040, first input unit 2050, second input unit 2060, simulator unit 2070, output unit 2080, communication unit 2090, control unit 2100 It includes.

The server room database unit 2010 stores a plurality of server room data.

The server room data may include one or more of the structure, internal temperature, and internal humidity of the server room.

The structure of the server room means any information about the space of the server room including the space shape, floor area, and ceiling area of the server room.

The air conditioning database unit 2020 stores a plurality of air conditioning data.

The air conditioning data may include one or more of data regarding power consumption of the air conditioning apparatus and temperature, humidity, wind speed, air volume, and air flow of air supplied from the air conditioning apparatus to the guide space of the server room. have.

The server rack database unit 2030 stores a plurality of server rack data.

The server rack data may include data related to power consumption of the server rack 100. The power consumption of the server rack 100 can be obtained from model information of the server rack 100. Alternatively, the power consumption of the server rack 100 may be data obtained by actually operating the server rack 100.

The memory unit 2040 stores upper surface temperature data in the server room.

The upper surface temperature data in the server room stored in the memory unit 2040 may be data obtained from the server room in which the server rack 100 and the air conditioner are mounted and actually operated.

The first input unit 2050 may include one or more server room data selected by a user in the server room database unit 2010, one or more air conditioning data selected by a user in the air conditioning database unit 2020, and the server rack database unit ( In 2030), one or more server rack data selected by the user may be input, respectively.

The second input unit 2060 may input an arrangement position of the selected server rack 100 inside the selected server room.

Here, the server room means a server room having one or more server room data selected by a user in the server room database unit 2010. In addition, the server rack 100 refers to a server rack 100 having one or more server rack data selected by a user in the server rack database unit 2030.

For example, the user may select one server room data (server room data A) from the server room database unit 2010 in which a plurality of server room data are stored, and a server rack in which a plurality of server rack data are stored. Five server rack data (server rack data A, B, C, D, E) may be selected from the database unit 2030.

The server room data A is data of server room A among a plurality of server rooms, and the server rack data A, B, C, D, and E are data of server racks A, B, C, D, and E of a plurality of server racks. to be.

The second input unit 2060 is a server rack A, B, C, D, E having the server rack data A, B, C, D, E selected by the user in the server rack database unit 2030, It is arranged inside the server room A having the server room data A selected by the server room database unit 2010 by the user.

The server room interior may be represented by 2D or 3D modeling so that the user can place the server rack 100 selected through the second input unit 2060 at a more accurate point in the selected server room.

The simulator unit 2070 performs analysis of the surface temperature inside the server room using CFD simulation based on the values input from the first input unit 2050 and the second input unit 2060. The analyzed upper surface temperature value in the server room is transmitted to the control unit 2100.

The output unit 2080 outputs an air conditioning state of the server room. For example, the output unit 2080 may include at least one of an audio output unit and a display unit.

The air conditioning state of the server room may include one or more of air conditioning efficiency and air conditioning risk.

In addition, the air conditioning state of the server room may be divided and output for each unit area of the server room.

The unit area of the server room may be output in one of a normal state, a hot spot state, or an over-cooling state.

The communication unit 2090 is configured to enable mutual data communication between the sensing unit, the air conditioning device, the control unit 2100, and various electronic components.

In addition, the communication unit 2090 is the server room database unit 2010, the air conditioning database unit 2020, the server rack database unit 2030, the memory unit 2040, the first input unit 2050, the The second input unit 2060, the simulator unit 2070, the output unit 2080, is configured to enable mutual data communication between the control unit 2100.

The control unit 2100 matches the top surface temperature value in the server room acquired by the simulator unit 2070 with the top surface temperature data in the server room stored in the memory unit 2040 to match the unit area of the server room. And/or the air-conditioning state of the entire area can be calculated.

For example, the controller 2100 is within the upper surface temperature value and the setting range of the server room obtained from the simulator unit 2070 among the upper surface temperature data in the server room stored in the memory unit 2040. The air condition of the unit area and/or the entire area of the server room may be calculated based on the closest data.

The controller 2100 may determine the air conditioning state of the server room to be one of a normal state, a hot spot state, and an overcooling state for each unit area of the server room.

Furthermore, the control unit 2100, while changing the arrangement position of the server rack 100 inside the server room so that the air conditioning state of the unit area of the server room is all normal, the optimum of the server rack 100. You can select the placement location.

Hereinafter, a method for evaluating the air conditioning state of the server room according to the first embodiment using the air conditioning state evaluation system 2000 of the server room according to an embodiment of the present invention described above will be described.

4 is a schematic flowchart of a method for evaluating an air conditioning state of a server room according to a first embodiment of the present invention, and FIG. 6 is a server room in an air conditioning state evaluation system of a server room according to an embodiment of the present invention It is a schematic diagram showing the air conditioning state for each unit area of.

According to this embodiment, as shown in FIG. 4, first, the user sets one or more server room data in the server room database unit 2010 in which a plurality of server room data are stored (S110).

Specifically, the user selects and inputs server room data required by the plurality of server room database units 2010 through the first input unit 2050.

In addition, the user sets one or more air conditioning data in the air conditioning database unit 2020 in which a plurality of air conditioning data are stored (S120).

Specifically, the user selects and inputs air conditioning data required by the plurality of air conditioning database units 2020 through the first input unit 2050.

In addition, the user sets one or more server rack data in the server rack database unit 2030 in which a plurality of server rack data are stored (S130).

Specifically, the user selects and inputs server rack data required by the plurality of server rack database units 2030 through the first input unit 2050.

The step of setting the server room data (S110), the step of setting the air conditioning data (S120), and the step of setting the server rack data (S130) may be performed in any order or simultaneously.

For example, as in this embodiment, setting the server room data (S110), setting the air conditioning data (S120), and setting the server rack data (S130) in order of each data. Can be set.

Alternatively, the step of setting the air conditioning data (S120) may be performed first, and then the step of setting the server room data (S110) and the step of setting the server rack data (S130), It may also proceed to another implementation step.

The server rack 100 having the set server rack data is simulated and placed inside the server room having the set server room data (S140).

Here, the server room in which the server rack 100 is simulated is a server room having one or more server room data selected by a user in the server room database unit 2010. In addition, the server rack 100 refers to a server rack 100 having one or more server rack data selected by a user in the server rack database unit 2030.

For example, the user may select one server room data (server room data A) from the server room database unit 2010 in which a plurality of server room data are stored, and in which the plurality of server rack data are stored. In the server rack database unit 2030, five server rack data (server rack data A, B, C, D, E) may be selected.

The server room data A is data of server room A among a plurality of server rooms, and the server rack data A, B, C, D, and E are data of server racks A, B, C, D, and E of a plurality of server racks. to be.

Specifically, the user has the server rack data A, B, C, D, E selected by the server rack database unit 2030 through the second input unit 2060, server rack A, B, C, D, E can be simulated and placed inside the server room A having the server room data A selected by the server room database unit 2010.

The control unit 2100 calculates the air conditioning state of the server room according to the arrangement position of the server rack 100 through analysis of the upper surface temperature inside the server room using CFD simulation (S150).

Specifically, the control unit 2100 matches the upper surface temperature value in the server room obtained from the simulator unit 2070 with the upper surface temperature data in the server room stored in the memory unit 2040 to match the server room. It is possible to calculate the air-conditioning status of each unit area and of the entire area.

In addition, the controller 2100 may determine the air conditioning state of the server room to be one of a normal state, a hot spot state, and an overcooling state for each unit area of the server room.

Subsequently, as shown in FIG. 6, the air conditioning state of the server room calculated by the control unit 2100 is output using the output unit 2080 such as an audio output unit or a display unit for each unit area or for the entire area. (S160).

Accordingly, the user can set the air conditioning state of the virtual driving server room according to the arrangement position of the server rack 100 based on the server room data, the air conditioning data, and the server rack data currently set through the output unit 2080. Can be checked immediately.

If the air conditioning status of each unit area of the virtual driving server room is determined to be normal, the user is the same as the currently set server room data, the air conditioning data, and the server rack data, and the currently deployed server rack. It is possible to implement an actual server room in the same manner as the arrangement position of (100).

Accordingly, in finding the optimal location of the server rack 100 in the specified server room, the server rack 100 is actually placed and the air conditioning condition evaluation system 2000 of the server room and its evaluation method without the need to actually operate the server rack 100 As a result, it is possible to quickly find an optimal placement position of the server rack 100 without incurring large costs.

The air conditioning state of the server room may include one or more of air conditioning efficiency and air conditioning risk. The air conditioning efficiency may be determined as good, normal, or poor according to a preset criterion, and the air conditioning risk may also be determined as safety, caution, danger, and the like.

On the other hand, if all of the air conditioning conditions for each unit area of the virtual driving server room are not determined to be normal, that is, in some unit areas, the air conditioning state is determined to be a hotspot state or an overcooling state, the user may output the output unit 2080. This makes it possible to recognize this situation intuitively.

Subsequently, the user may re-position the server rack 100 in another location in the server room in consideration of the location of the unit area of the server room in a hotspot state and the position of the unit area of the server room in an overcooled state. (S140), and the result can be checked by the user again through steps S150 and S160.

Hereinafter, a method for evaluating the air conditioning state of the server room according to the second embodiment using the air conditioning state evaluation system 2000 of the server room according to an embodiment of the present invention will be described.

5 is a schematic flowchart of a method for evaluating an air conditioning condition in a server room according to a second embodiment of the present invention.

According to this embodiment, as illustrated in FIG. 5, the user sets one or more server room data in the server room database unit 2010 in which a plurality of server room data are stored (S210 ).

The user may select and input server room data required by the plurality of server room database units 2010 by the first input unit 2050.

In addition, the user sets one or more air conditioning data in the air conditioning database unit 2020 in which a plurality of air conditioning data are stored (S220).

The user may select and input air conditioning data required by the plurality of air conditioning database units 2020 by the first input unit 2050.

In addition, the user sets one or more server rack data in the server rack database unit 2030 in which a plurality of server rack data are stored (S230).

The user may select and input server rack data required by the plurality of server rack database units 2030 by the first input unit 2050.

The above-described setting of the server room data (S210), setting of the air conditioning data (S220), and setting of the server rack data (S230) may be performed in any order or simultaneously.

For example, as in the present embodiment, setting the server room data (S210), setting the air conditioning data (S220), and setting the server rack data (S230) in order of each data. Can be set.

Alternatively, the step of setting the air conditioning data (S220) is performed first, and then the step of setting the server room data (S210) and the step of setting the server rack data (S230), It may also proceed to another implementation step.

The controller 2100 simulates and places the server rack 100 having the set server rack data inside the server room having the set server room data (S240).

Here, the server room in which the server rack 100 is simulated is a server room having one or more server room data selected by a user in the server room database unit 2010. In addition, the server rack 100 refers to a server rack 100 having one or more server rack data selected by a user in the server rack database unit 2030.

The controller 2100 calculates the air conditioning state of the server room according to the arrangement position of the server rack 100 through analysis of the top surface temperature inside the server room using CFD simulation (S250).

Specifically, the control unit 2100 matches the upper surface temperature value in the server room obtained from the simulator unit 2070 with the upper surface temperature data in the server room stored in the memory unit 2040 to match the server room. It is possible to calculate the air-conditioning condition of each unit area and of the entire area.

The controller 2100 may determine the air conditioning state of the server room to be one of a normal state, a hot spot state, and an overcooling state for each unit area of the server room.

The control unit 2100 changes the arrangement position of the server rack 100 inside the server room so that the air conditioning state of the unit area of the server room is all normal, and the optimum placement position of the server rack 100 is changed. It is selected (S260 to S280).

Specifically, the control unit 2100 determines whether the air conditioning state of the unit area of the server room is a hot spot state (S260).

When it is determined that the air conditioning state of the unit area of the server room is a hot spot state, the control unit 2100 rearranges the server rack 100 at a position different from the position of the server rack 100 previously arranged in step S240. (S240), and then proceeds to the next step.

If it is determined that the air conditioning state of the unit area of the server room is not a hot spot state, the controller 2100 determines whether the air conditioning state of the unit area of the server room is an overcooling state (S270).

If it is determined that the air conditioning state of the unit area of the server room is an overcooling state, the control unit 2100 moves the server rack 100 to a position different from the position of the server rack 100 previously arranged in step S240. Relocate (S240), and then proceed to the next step.

If it is determined that the air conditioning state of the unit area of the server room is not an overcooling state, the controller 2100 determines the air conditioning state of the unit area of the server room as a normal state.

The control unit 2100 repeatedly performs steps S240 to S270 for the entire unit area of the server room, and when all air conditioning conditions of the entire unit area of the server room are determined to be normal, the currently set server room data, Based on the air conditioning data and the server rack data, the placement position of the currently deployed server rack 100 is selected as an optimal placement position (S280).

The optimal placement position of the selected server rack 100 may be output using an output unit 2080 such as an audio output unit or a display unit.

As described above, the server rack 100 is actually disposed, and the server rack 100 can be quickly and without incurring significant cost as an air conditioning condition evaluation system 2000 and its evaluation method in the server room without actually operating the server room. Can find the optimal placement position.

As described above, the present invention has been described with reference to embodiments shown in the drawings, but this is only for explaining the invention, and those skilled in the art to which the present invention pertains various modifications or equivalents from the detailed description of the invention It will be understood that one embodiment is possible.

Therefore, the true scope of the present invention should be determined by the technical spirit of the claims.

1000: Air conditioning control system in server room
2000: Air conditioning condition evaluation system in server room
2010: Server room database
2020: Air conditioning database department
2030: Server rack database
2040: memory unit
2050: first input unit
2060: second input unit
2070: Simulator part
2080: output
2090: Communication Department
2100: control unit

Claims (15)

Setting one or more server room data in a server room database unit in which a plurality of server room data are stored;
Setting one or more air conditioning data in an air conditioning database unit in which a plurality of air conditioning data are stored;
Setting one or more server rack data in a server rack database unit in which a plurality of server rack data are stored;
Placing a server rack having the set server rack data in a server room having the set server room data; And
And calculating an air conditioning state of the server room according to an arrangement position of the server rack through analysis of an upper surface temperature inside the server room using CFD (Computational Fluid Dynamics) simulation. Method of state evaluation. According to claim 1,
And outputting the air conditioning state of the server room to an output unit. The method according to claim 1 or 2,
The air conditioning state of the server room is divided into unit areas of the server room, and the unit area of the server room is one of a normal state, a hot spot state, and an over-cooling state. Method for evaluating the air conditioning condition of a server room, characterized in that the condition is selected. According to claim 3,
And selecting the optimal placement position of the server rack while changing the placement position of the server rack inside the server room so that the air conditioning state of the unit area of the server room is all normal. How to evaluate the air conditioning of a room. The method according to claim 1 or 2,
The air conditioning state of the server room, the air conditioning efficiency evaluation method of the server room, characterized in that it comprises at least one of the air conditioning efficiency and the risk of air conditioning. The method according to claim 1 or 2,
The step of setting the server room data, the step of setting the air conditioning data, and the step of setting the server rack data may be performed in any order or simultaneously. The method according to claim 1 or 2,
The server room data, air conditioning condition evaluation method of the server room, characterized in that it comprises at least one of the data related to the structure, internal temperature, and internal humidity of the server room. The method according to claim 1 or 2,
The air conditioning data includes one or more of data regarding power consumption of the air conditioning apparatus and temperature, humidity, wind speed, air volume, and air flow of air supplied from the air conditioning apparatus to the guide space of the server room. Method of evaluating the air conditioning condition of the server room, characterized in that. The method according to claim 1 or 2,
The server rack data, air conditioning condition evaluation method of the server room, characterized in that it comprises data about the power consumption of the server rack. The method of claim 9,
The data related to the power consumption of the server rack and the surface temperature data inside the server room provided when analyzing the surface temperature inside the server room using the CFD simulation are obtained from the server room actually operated. Method for evaluating air conditioning condition of server room. A server room database unit in which a plurality of server room data are stored;
An air conditioning database unit storing a plurality of air conditioning data;
A server rack database unit in which a plurality of server rack data are stored;
A first input unit for inputting the server room data, the air conditioning data, and the server rack data selected by a user from the server room database unit, the air conditioning database unit, and the server rack database unit;
A second input unit for inputting a placement position of the server rack having the server rack data selected by the user in a server room having the server room data selected by the user;
A memory unit for storing upper surface temperature data in the server room;
A simulator unit performing analysis of the upper surface temperature inside the server room using CFD simulation based on the values input from the first input unit and the second input unit; And
And a control unit that calculates an air conditioning state of the server room by matching the upper surface temperature value in the server room obtained from the simulator unit with the upper surface temperature data in the server room stored in the memory unit. Server room air conditioning condition evaluation system. The method of claim 11,
And an output unit for outputting the air conditioning state of the server room. The method of claim 11 or 12,
The control unit, the air conditioning state evaluation system of the server room, characterized in that for determining the unit air conditioning state of the server room in one of the normal state, hot spot state, overcooling state. The method of claim 13,
The control unit selects an optimal placement position of the server rack while changing the arrangement position of the server rack inside the server room so that the air conditioning state of the unit area of the server room is all normal. Air conditioning condition evaluation system. The method of claim 11,
The air conditioning condition evaluation system of the server room, characterized in that the upper surface temperature data in the server room stored in the memory unit is data obtained from the actually operated server room.

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