KR101896217B1 - server cooling control system using network - Google Patents

Abstract

The present invention relates to a server management system using a network, capable of preventing a malfunction or down of a server, which comprises: a first server rack (20) having a first identification code (C1) for identification; a first event sensing unit (30) generating a first event signal (S1); a first cooling air generating unit (40); a first cooling air guide unit (50); a second server rack (20′) having a second identification code (C2) for identification; a second event sensing unit (30′) for generating a second event signal (S2); a second cooling air generating unit (40′); a second cooling air guide unit (50′); and a management server (60).

Description

[0001] The present invention relates to a server management system using a network,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a server management system using a network, and more particularly, to a server management system using a network in which a plurality of servers installed at a remote location can be used when an event occurs.

Generally, a server is operated in a business place such as a public institution, a corporation, a hospital, or the like to share a file management, a data processing, a program support, a printer or a fax, Computer). In this case, in a small-sized business where the number of clients is several, all operations can be performed by one server. However, when the number of clients is several hundreds, it is necessary to operate several servers. The server continues to process data 24 hours a day, and the CPU of the server is equipped with a separate cooler to cool the heat generated by processing the data.

On the other hand, large-scale business sites that operate multiple servers have servers installed in the data center where the constant temperature and humidity devices are installed. However, since there is no capacity to operate a data center in a small business site, .

However, since most of the corners of a business are not well ventilated, when the air conditioner stops operating during summer or after work, the temperature of the place where the server is placed is frequently excessively increased. In this case, Cooling did not work properly and the server went down frequently.

Also, as time passes, fatigue accumulates in the heat-radiating fan constituting the cooler. As a result, the cooling efficiency of the cooler gradually decreases and the heat-radiating fan suddenly stops. In this case, the CPU is not cooled and the server is down.

In this way, whatever the cause, if the CPU is not properly cooled, the server may be down and causing extreme confusion.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a system and method for preventing a malfunction or a down of a server by rapidly supplying cooling air to the server when an event occurs, A server management system using a network capable of managing a plurality of networks.

It is another object of the present invention to provide a server management system using a network that can facilitate maintenance by transmitting an event situation of a server in which a server temperature excessively increases to a management server through a network.

In order to achieve the above object, a server management system using a network according to the present invention is characterized in that a first server (10) for processing data is seated, and a first server having a first identification code (C1) A server rack 20; A first event sensing unit 30 for generating a first event signal S1 when an event event different from usual occurs in the first server 10; A first cooling air generator (40) installed in the first server rack (20) and selectively supplying first cooling air for cooling to the first server (10); A first cooling air guide portion (50) for guiding the first cooling air generated in the first cooling air generating portion (40) into the first server (10); A second server rack (20 ') having a second identification code (C2) for identification, to which a second server (10') for processing data is seated; A second event detection unit 30 'for generating a second event signal S2 when an event situation different from usual occurs in the first server 10; A second cooling air generator 40 'installed in the second server rack 20' and selectively supplying second cooling air for cooling into the second server 10 '; A second cooling air guide 50 'for guiding the second cooling air generated in the second cooling air generator 40' into the second server 10 '; And the first and second server racks 20 and 20 'are connected to the network N. The first and second event signals S1 and S2 and the first and second identification codes C1 and C2, (C2 ') to control the first and second cooling air generators 40 and 40' to supply the first and second cooling air to the first and second servers 10 and 10 ' A management server (60);
The first and second event sensing units 30 and 30 'are provided in the first and second ceiling housings 15 and 15' of the first and second servers 10 and 10 ' 2 brackets 31 and 31 '; The first and second infrared sensors 32 and 32 'are installed opposite to the first and second coolers 12 and 12' to measure the heat generated by the first and second coolers 12 and 12 ' ) 32 '; When the temperature T of the first and second coolers 12 and 12 measured by the first and second infrared sensors 32 and 32 'is higher than a predetermined warning temperature T1, A first and second event signal generators 34 and 34 'for generating two event signals S1 and S2; And a first and second signal transmission units 35 and 35 'for transmitting the first and second event signals S1 and S2 to the management server 60 via the network N .

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The first and second event sensing units 30 and 30'contact noise generated by the first and second fans 12a and 12a 'constituting the first and second coolers 12 and 12 (33 ') < / RTI > The first and second signal transmitters 35 and 35 'measure the noise of the predetermined warning frequency N1 from the noise A measured by the first and second acoustic sensors 33 and 33' And generates the first and second event signals S1 and S2.

In the present invention, the first and second brackets 31 and 31 'include first and second lower brackets 31a and 31b positioned on the lower surfaces of the first and second ceiling housings 15 and 15' The first and second upper brackets 31b and 31b 'are positioned on the lower surfaces of the first and second ceiling housings 15 and 15' And the first and second heat insulating sound absorbing layers 31c and 31c positioned between the first and second lower brackets 15 'and 31a' and 31a '.

In the present invention, the first and second infrared sensors 32 and 32 'and the first and second acoustic sensors 33 and 33' are provided on the first and second lower brackets 31a and 31a ' And is directed toward the first and second coolers 12 and 12 '.

In the present invention, the first and second cooling air guiding portions 50 and 50 'may include a first and a second hose 51 connected to the first and second cooling air generating portions 40 and 40' A first connector 52 and a second connector 52 'formed on the second bracket 31' to selectively connect the first and second hoses 51 and 51 ' And first and second injection nozzles 53 and 53 'which are connected to the first and second connectors 52 and 52' so as to face the first and second coolers 12 and 12 '.

According to the present invention, by employing the first and second event sensing units, the first and second cooling air generating units, and the first and second cooling air guide units independently operating with the first and second servers, The first and second cooling air generated by the first and second cooling air generators are quickly supplied to the corresponding server and the malfunction of the corresponding server is prevented Down can be prevented. In particular, the event status of the server is transmitted to the management server through the network N, so that the manager can immediately recognize the event status of the server, thereby enabling reliable maintenance before the server is down.

1 is a diagram for explaining the overall configuration of a server management system using a network according to the present invention;
FIG. 2 is a perspective view showing the first and second server racks of FIG. 1,
FIG. 3 is a front view of the first and second servers seated in the first and second server racks of FIG. 2;
FIG. 4 is a partial side sectional view for explaining the internal configuration of the first and second servers of FIG. 3;
FIG. 5 is a block diagram illustrating a first and second event detection unit for detecting an event occurring in the first and second server racks of FIG. 4, FIG. 6 is a block diagram for explaining that the first and second cooling air generating units for generating cooling air are connected to the management server by the network;
FIG. 6 is an enlarged view of the first and second event detection units and the first and second cooling units of FIG. 4; FIG.

Hereinafter, a server management system using a network according to the present invention will be described with reference to the accompanying drawings.

In the following examples, the singular forms "a", "an" and "the" include plural referents unless the context clearly dictates otherwise.

In the following embodiments, terms such as inclusive or possessive are intended to mean that a feature, or element, described in the specification is present, and does not preclude the possibility that one or more other features or elements may be added.

In the following embodiments, when a part of a film, an area, a component or the like is on or on another part, not only the case where the part is directly on the other part but also another film, area, And the like.

In the drawings, components may be exaggerated or reduced in size for convenience of explanation. For example, the size and thickness of each component shown in the drawings are arbitrarily shown for convenience of explanation, and thus the present invention is not necessarily limited to those shown in the drawings.

If certain embodiments are otherwise feasible, the particular process sequence may be performed differently from the sequence described. For example, two processes that are described in succession may be performed substantially concurrently, and may be performed in the reverse order of the order described.

FIG. 1 is a perspective view illustrating an entire configuration of a server management system using a network according to the present invention, which is an excerpt of the first and second server racks of FIG. 1 of FIG. 2. FIG. FIG. 4 is a partial side sectional view for explaining the internal configuration of the first and second servers of FIG. 3; FIG.

FIG. 5 is a block diagram illustrating a first and second event detection unit for detecting an event occurring in the first and second server racks of FIG. 4, FIG. 6 is a block diagram for explaining that the first and second cooling air generators for generating cooling air are connected to the management server by the network, and FIG. 6 is a block diagram for explaining the first and second cooling air generators And Fig.

As shown in the figure, a server management system using a network according to the present invention includes a first server 10 for processing data, a first server rack 20 having a first identification code C1 for identification, )and; A first event detection unit 30 for generating a first event signal S1 when an event situation different from usual occurs in the first server 10; A first cooling air generator 40 installed in the first server rack 20 for selectively supplying first cooling air for cooling to the first server 10; A first cooling air guide unit 50 for guiding the first cooling air generated in the first cooling air generator 40 into the first server 10; A second server rack (20 ') having a second identification code (C2) for identification, to which a second server (10') for processing data is seated; A second event sensing unit 30 'for generating a second event signal S2 when an event situation different from usual occurs in the first server 10; A second cooling air generator 40 'installed in the second server rack 20' and selectively supplying second cooling air for cooling into the second server 10 '; A second cooling air guide 50 'for guiding the second cooling air generated in the second cooling air generator 40' to the inside of the second server 10 '; The first and second server racks 20 and 20 'are connected to the network N. The first and second event signals S1 and S2 and the first and second identification codes C1 and C2 C2 'to control the first and second cooling air generators 40 and 40' to supply the first and second cooling air to the first and second servers 10 and 10 ' ); ≪ / RTI >

In the present embodiment, the number of servers is limited to two servers for ease of explanation, but it is needless to say that the number of servers can be increased. Accordingly, the number of the server rack, the event sensing unit, and the cooling air guide unit corresponding to the server can also be increased.

The first and second servers 10 and 10 'are connected to a plurality of clients (computers) through a network N such as a LAN or the Internet and perform file management, data processing, program support among printers, Share.

Each of the first and second servers 10 and 10 'is provided with a first and second CPU 11, a memory, a hard drive or an SSD drive, a communication port, and the like, The first and second CPUs 11 and 12 are provided with first and second coolers 12 and 12 'for direct heat dissipation. The first and second coolers 12 and 12 'are formed of a plurality of radiating fins and air is supplied to the first and second coolers 12 and 12' The first and second fans 12a and 12a 'are installed.

The first server rack 20 and the second server rack 20 'have substantially the same configuration and have a first identification code C1 for identification and a second identification code C2. As shown in FIGS. 2 and 3, the first and second server racks 20 and 20 'include first and second rack bodies 21 and 21' supported on the ground, A plurality of first and second shelves 22 and 22 'provided on the rack bodies 21 and 21' and a plurality of second racks 22 and 22 'installed on the upper sides of the first and second rack bodies 21 and 21' And first and second blowers 23 and 23 'for blowing air into the first and second rack bodies 21 and 21'.

The first event sensing unit 30 generates a first event signal S1 when an event situation different from usual occurs in the first server 10. 4 and 6, the first event sensing unit 30 includes a first bracket 31 installed in the first ceiling housing 15 of the first server 10; An infrared sensor 32 installed opposite to the first cooler 12 to measure the heat generated by the first cooler 12 in a non-contact manner; A first acoustic sensor 33 for measuring a noise generated in the first fan 12a constituting the first cooler 12; When the temperature T of the first cooler 12 measured by the first infrared sensor 32 is higher than the predetermined warning temperature T1 or the noise T measured by the first acoustic sensor 33 A first event signal generator 34 for generating a first event signal S1 when noise of the set warning frequency N1 is measured; And a first signal transmitter 35 for transmitting the first event signal S1 to the management server 60 via the network N. [

The second event sensing unit 30 'is substantially the same as the first event sensing unit 30. The second event sensing unit 30' generates a second event signal S2 when an event other than usual occurs in the second server 10 ' Occurs. 4 and 6, the second event detection unit 30 'includes a second bracket 31' installed on the second ceiling housing 15 'of the second server 10' and; A second infrared sensor 32 'installed opposite to the second cooler 12' and measuring the heat generated by the second cooler 12 'in a non-contact manner; A second acoustic sensor 33 'for measuring noise generated in the second fan 12a' constituting the second cooler 12 '; The temperature T of the second cooler 12 'measured on the second infrared sensor 32' is higher than the preset warning temperature T1 or the measured noise T A on the second acoustic sensor 33 ' A second event signal generating unit 34 'for generating a second event signal S2 when the preset warning frequency N1 is measured in the first event signal generating unit 34'; And a second signal transmission unit 35 'for transmitting the second event signal S2 to the management server 60 via the network N. [

As shown in FIG. 6, the first and second brackets 31 and 31 'include first and second lower brackets 31a and 31b positioned on the lower surfaces of the first and second ceiling housings 15 and 15' First and second upper brackets 31b and 31b 'positioned on the lower surfaces of the first and second ceiling housings 15 and 15' And the first and second heat insulating sound absorbing layers 31c and 31c positioned between the first and second lower brackets 15 'and 31a' and 31a '.

The first and second infrared sensors 32 and 32 'and the first and second acoustic sensors 33 and 33' are connected to the first and second lower brackets 31a and 31a ' The first and second event signal generators 34 and 34 'and the first and second signal transmitters 35 and 35' are installed in the first and second upper brackets 31b and 31b ' (35 ').

The first and second heat insulating sound absorbing layers 31c and 31c prevent external noise from the first and second servers 10 and 10 'from being transmitted to the first and second acoustic sensors 33 and 33'. Therefore, the first and second acoustic sensors 33 and 33 'will not be disturbed by the external noise environment of the first and second servers 10 and 10' Noise can be accurately measured.

The first and second infrared sensors 32 and 32 'contactlessly detect the heat conducted directly to the first and second coolers 12 and 12' by the first and second CPUs 11 and 11 ' . For this purpose, the first and second infrared sensors 32 and 32 'are supported by the support rods R extending downward from the first and second lower brackets 31a and 31b, 12 ', which are not admitted by the first and second coolers 12, 12'.

The first and second acoustic sensors 33 and 33 'measure the noise A generated by the first and second fans 12a and 12a constituting the first and second coolers 12 and 12' .

For reference, lubricating oil is contained inside the motor constituting the first and second fans 12a and 12a 'for smooth rotation of the rotor. The lubricating oil is supplied to the first and second fans 12a and 112a' It is gradually consumed in the process of operation, so that the noise (A), which was not initially generated, is gradually generated. If the lubricating oil is completely exhausted at any moment, the rotor wears rapidly and the first and second fans 12a and 12a 'are stopped, and the operation of the first and second coolers is stopped. Therefore, when operating the server, the first and second fans are periodically replaced. On the other hand, the first and second fans are not periodically replaced by a small-sized server.

The first and second event signal generators 34 and 34 'detect a predetermined warning frequency A1 from the noise A measured by the first and second sound sensors 33 and 33' And generates an event signal S2. The predetermined warning frequency A1 is a fricative sound generated when the lubricating oil is almost exhausted from the rotor constituting the first and second fans, and when the fricative sound is generated, it is a signal that the rotor (first and second fans) will be stopped soon .

The first cooling air generator 40 is installed in the first server rack 20 to provide cooling air for cooling the first server 10 and the second cooling air generator 40 ' Is provided in the rack 20 'to provide cooling air for cooling the second server 10', and has substantially the same configuration. As shown in FIG. 2, the first and second cooling air generators 40 are installed on the rear side of the first and second server racks 20 and 20 ' A cooling circuit including a compressor is used to generate a cooling temperature lower than the temperature of the space in which the first and second server racks 20 and 20 'are disposed. The first and second cooling air generating units 40 and 40 ') Is a known technique, so that further detailed description is omitted.

The first and second cooling air guide portions 50 and 50 'are cooled by the first and second cooling air generated by the first and second cooling air generating portions 40 and 40' To guide the air into the first and second servers 10 and 10 '. The first and second cooling air guiding portions 50 and 50 'include first and second hoses 51 and 51' connected to the first and second cooling air generating portions 40 and 40 ' First and second connectors 52 and 52 'formed on the bracket 31' and having the first and second hoses 51 and 51 'selectively engaged; And first and second injection nozzles 53 and 53 'which are connected to the first and second connectors 52 and 52' so as to face the first and second coolers 12 and 12 '.

The first and second hoses 51 and 51 'are made of a flexible material and can be bent in a state of being elongated according to the positions of the first and second connectors.

The first and second injection nozzles 53 and 53 'are connected to the first and second hoses 51 and 51' in such a manner that the first and second cooling air are supplied to the first and second CPUs 11 and 11 ' To the upper side of the first and second coolers 12 and 12 '. Accordingly, even if the first and second coolers 12 and 12 'are stopped, the first and second cooling air cools the first and second coolers 12 and 12' to cool the first and second CPUs 11 and 11 ' Can be cooled. Particularly, since the first and second cooling air have a lower temperature than room temperature due to the thermoelectric element or the compressor, the first and second coolers 12 and 12 'can be cooled rapidly.

The first and second event sensing units 30 and 30 ', the first and second cooling air generating units 40 and 40', and the first and second cooling air guide units 50 and 50 ' The first and second servers 10 and 10 'do not depend on the programmable operation of the first and second servers 10 and 10' ', The first and second cooling air generators 40 and 40', and the first and second cooling air guides 50 and 50 'operate normally.

The management server 60 is connected to the first and second server racks 20 and 20 'by the network N and receives the first and second event signals S1 and S2 So that the first and second cooling air generators 40 and 40 'supply the first and second cooling air to the first and second servers 10 and 10' in cooperation with the identification codes C1 and C2 . At this time, when the first and second cooling air are supplied to the first and second servers 10 and 10 ', the management server 60 notifies the administrator of an event situation in a server mounted on a remote server rack having a specific identification code And notifies the occurrence of the event through the wired / wireless communication so that the cause of the event can be handled.

As described above, according to the present invention, the first and second event sensing units 30 and 30 ', the first and second cooling air generating units 40 and 40', which operate independently of the first and second servers 10 and 10 ' The first and second CPUs 11 and 11 'which are the brains of the first and second servers 10 and 10' are employed by employing the first and second cooling air guide portions 50 and 50 ' When an excessive rising event occurs, the first and second cooling air generated by the first and second cooling air generators 40 and 40 are quickly supplied to the server, And can be prevented.

In particular, the event status of the server is transmitted to the management server 60 via the network N, so that the administrator can immediately recognize the event status of the server, thereby enabling reliable maintenance before the server goes down .

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

10, 10 '... First and second servers 11, 11' ... First and second CPUs
12, 12 '... first and second coolers 12a, 12a' ... first and second fans
20, 20 '... first and second server racks 21, 21' ... first and second rack bodies
22, 22 '... first and second shelves 23, 23' ... first and second blowers
30, 30 '... first and second event detection units 31 and 31; ... 1st and 2nd brackets
31a, 31a '... First and second lower brackets 31b, 31b' ... First and second upper brackets
31c, 31c '... first and second heat insulating sound absorbing layers 32, 32' ... first and second infrared sensor
33, 33 '... first and second acoustic sensors 34, 34' ... first and second event signal generators
35, 35 '... First and second signal transmission units 40, 40' ... First and second cooling air generators
50, 50 '... first and second cooling air guide portions 51, 51' ... first and second hoses
52, 52 '... First and second connectors 53, 53 '... First and second injection nozzles
60 ... management server

Claims (6)

A first server rack (20) having a first identification code (12) for identification, on which a first server (10) for processing data is seated;
A first event sensing unit 30 for generating a first event signal S1 when an event event different from usual occurs in the first server 10;
A first cooling air generator (40) installed in the first server rack (20) and selectively supplying first cooling air for cooling to the first server (10);
A first cooling air guide (50) for guiding the first cooling air generated in the first cooling air generator (40) into the first server (10);
A second server rack (20 ') having a second identification code (C2) for identification, to which a second server (10') for processing data is seated;
A second event detection unit 30 'for generating a second event signal S2 when an event situation different from usual occurs in the first server 10;
A second cooling air generator 40 'installed in the second server rack 20' and selectively supplying second cooling air for cooling into the second server 10 ';
A second cooling air guide 50 'for guiding the second cooling air generated in the second cooling air generator 40' into the second server 10 '; And
The first and second event signals S1 and S2 and the first and second identification codes C1 and C2 are connected to the first and second server racks 20 and 20 ' (10 ') in cooperation with the first and second cooling air generation units 40 and 40' in cooperation with the first and second servers 10 and 10 ' And a server (60)
The first and second event sensing units 30 and 30 'are provided in the first and second ceiling housings 15 and 15' of the first and second servers 10 and 10 ' 2 brackets 31 and 31 '; The first and second infrared sensors 32 and 32 are disposed opposite to the first and second coolers 12 and 12 'to measure the heat generated by the first and second coolers 12 and 12' (32 '); When the temperature T of the first and second coolers 12 and 12 measured by the first and second infrared sensors 32 and 32 'is higher than a predetermined warning temperature T1, A first and second event signal generators 34 and 34 'for generating two event signals S1 and S2; And a first and second signal transmission units 35 and 35 'for transmitting the first and second event signals S1 and S2 to the management server 60 via the network N A server management system using a network. delete The apparatus of claim 1, wherein the first and second event sensing units (30, 30 '
The first and second acoustic sensors 33 and 33 'for measuring the noise A generated by the first and second fans 12a and 12a' constituting the first and second coolers 12 and 12, Lt; / RTI >
The first and second signal transmitters 35 and 35 'measure the noise of the predetermined warning frequency N1 from the noise A measured by the first and second acoustic sensors 33 and 33' And generates the first and second event signals (S1, S2) when the first and second event signals (S1, S2) are received. 2. The apparatus according to claim 1, wherein the first and second brackets (31, 31 '
First and second lower brackets 31a and 31a 'positioned on the lower surfaces of the first and second ceiling housing 15 and 15'
First and second upper brackets 31b and 31b 'positioned on the lower surface of the first and second ceiling housings 15 and 15'
And a first and a second heat insulating sound absorbing layers 31c and 31c positioned between the first and second ceiling housing 15 and 15 'and the first and second lower brackets 31a and 31a' A server management system using a network. 5. The method of claim 4,
The first and second infrared sensors 32 and 32 'and the first and second acoustic sensors 33 and 33' are connected to the first and second lower brackets 31a and 31a ' (12 ', 12'). The refrigerator according to claim 1, wherein the first and second cooling air guide portions (50, 50 '
First and second hoses 51 and 51 'connected to the first and second cooling air generators 40 and 40'
A first connector 52 and a second connector 52 'formed on the second bracket 31' to selectively connect the first and second hoses 51 and 51 '
And first and second spray nozzles 53 and 53 'which are connected to the first and second connectors 52 and 52' so as to face the first and second coolers 12 and 12 ' A server management system using a network as a feature.

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