KR102030968B1 - Server management system using networks - Google Patents

Abstract

The present invention relates to a network control server management system. The network control server management system includes: a first server rack (20) in which a first server (10) for processing data is placed where the first server rack includes a first identification code (A1) for identification; a first dust sensing part (30) for sensing dust existing in the first server (10); a first event signal generating part (40) generating a first event signal (S1) when the concentration of the dust sensed by the first dust sensing part (30) becomes no less than a set warning concentration; a second server rack (20′) in which a second server (10′) for processing data is placed wherein the second server rack includes a second identification code (A2) for identification; a second dust sensing part (30′) for sensing dust accumulated in the second server (10′); a second event signal generating part (40′) generating a second event signal (S2) when the concentration of the dust sensed by the second dust sensing part (30′) becomes no less than a set warning concentration; and a management server (70) connected with the first and second server racks (20, 20′) through a network (N), and receiving the first and second event signals (S1, S2) and the first and second identification codes (A1, A2). Therefore, the present invention is capable of preventing a malfunction or breakage of a server caused by dust.

Description

Network Management Server Management System {Server management system using networks}

The present invention relates to a network control server management system, and more particularly, to a network server management system capable of detecting and appropriate sounding when an event situation occurs in a specific server at a remote location.

In general, servers in public institutions, corporations, hospitals, etc. share files management, data processing, program support, printers, faxes, and so on. Computer). In a small workplace with a large number of clients, all operations are possible with a single server, but if there are hundreds of clients, several servers must be operated. Each server operates 24 hours a day to process data. have.

However, because the server operates 24 hours a day, the electromagnetic field is always generated inside the server, which causes dust in the air to generate static electricity, and dust builds up on components inside the server over time. . These dusts generate static electricity in dry weather, generate electrical sparks, destroy precision parts, and cause overheating by preventing heat generation when they accumulate on the CPU or memory. Caused the server to crash.

The present invention was created in order to solve the above problems, when an event situation in which dust is excessively accumulated in a specific server among a plurality of servers installed in a remote place occurs, the management server detects this and is dispatched to the manager. It is an object of the present invention to provide a network control server management system that can be used to take action.

Another object of the present invention is to provide a network control server management system which automatically makes a response to lower the dust concentration when the dust concentration present inside the server becomes equal to or higher than the set warning concentration.

In order to achieve the above object, the network control server management system according to the present invention, the first server 10 for processing data seated on the first server rack 20 having a first identification code (A1) Is installed in, the first dust detection unit 30 for detecting the dust accumulated excessively inside the first server (10); Dust that is excessively accumulated in the second server 10 'is installed inside the second server 10' for data processing mounted on the second server rack 20 'having the second identification code A2. A second dust detector 30 'for sensing; A first event signal generator 40 generating a first event signal S1 when the concentration of dust detected by the first dust detector 30 is equal to or higher than a set warning concentration; A second event signal generator 40 'generating a second event signal S2 when the concentration of dust detected by the second dust detector 30' is equal to or higher than a set warning concentration; A first compressed air generator 50 installed in the first server rack 20 to generate compressed air; A second compressed air generating unit 50 'installed in the second server rack 20' to generate compressed air; First compressed air injection unit for instantaneously injecting the compressed air generated by the first compressed air generating unit 50 to the first server 10 in order to scatter the dust accumulated inside the first server 10 ( 60); Second compressed air injection unit for injecting the compressed air generated by the second compressed air generating unit 50 'to the second server 10' in order to scatter the dust accumulated inside the second server 10 ' (60 '); And the first and second server racks 20 and 20 'and the network N, wherein the first and second event signals S1 and S2 and the first and second identification codes A1 ( A2) includes a management server 70 is received; The first dust detection unit 30, the first detection unit bracket 31 is fixed to the inside of the first server body 11 of the first server 10 and the first detection unit bracket 31 The first light emitting part 32 is installed on one side and irradiates the light L, and the light L provided on the other side of the first sensing part bracket 31 is irradiated from the first light emitting part 32. A first concentration calculator 34 calculating a dust concentration based on a change in the amount of light partially shielded by dust between the receiving first light receiving unit 33 and the first light emitting unit 32 and the first light receiving unit 33; ); The second dust detection unit 30 'includes a second detection unit bracket 31' fixed inside the second server body 11 'of the second server 10' and the second detection unit bracket. A second light emitting part 32 'provided at one side of the 31' and irradiating light L, and a second light emitting part 32 'provided at the other side of the second sensing part bracket 31'. Dust on the basis of a change in the amount of light partially shielded by dust between the second light receiving unit 33 'and the second light receiving unit 32' and the second light receiving unit 33 'that receive the irradiated light L; A second concentration calculator 34 'that calculates the concentration; The first light emitting unit 32 and the first light receiving unit 33 on the first detection unit bracket 31 so that the first dust detection unit 30 can be easily installed on the first server body 11. ) And the first concentration calculation unit 34 are integrated into one module; The second light emitting part 32 'and the second light emitting part 32' on the second detecting part bracket 31 'can be easily installed on the second server main body 11'. It is characterized in that the two light-receiving unit 33 'and the second concentration calculation unit 34' is integrated into one module.

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In the present invention, the first compressed air generating unit 50 is installed in the main body of the first server rack 20, the first compression tank 51 and the first compression tank 51 is filled with compressed air A first compression pump 52 for supplying high pressure air to the air) and a first duct 53 installed on the rear surface of the first server rack 20 to communicate with the first compression tank 51; The second compressed air generating unit 50 'includes a second compression tank 51' and a second compression tank 51 ', which are installed in the main body of the second server rack 20' and are filled with compressed air. The second compression pump 52 'which supplies the high pressure air to the furnace and the second duct 53' which is installed at the rear of the second server rack 20 'and communicates with the second compression tank 51' Include.

In the present invention, the first compressed air injection unit 60 is installed in the first bracket 61 and the first bracket 61 fixed to the first server 10, the first duct A first distributor (62) in communication with (53) and a plurality of first distributor hoses (63) extending into the first server (10) as being connected to the first distributor (62); The second compressed air injection unit 60 'is provided with a second bracket 61' fixed to the second server 10 'and the second duct 61'. 53 ') and a plurality of second distribution hoses 63' extending into the second server 10 'as being connected to the second distributor 62' and connected to the second distributor 62 '. Include.

In the present invention, the first compressed air injection unit (60) further includes a first valve (64) installed between the first distributor (62) and the first duct (53); The second compressed air injection unit 60 'further includes a second valve 64' installed between the second distributor 62 'and the second duct 53'.

In the present invention, the first distribution hose (63) has a corrugated pipe shape to be variable in position inside the first server (10); The second distribution hose 63 ′ has a corrugated pipe shape to be variable in position inside the second server 10 ′.

According to the present invention, when the concentration of the dust present inside the first and second servers is greater than or equal to the setting, the first and second dust detection units detect this, and the first and second event signal generators include the first and second event signals (S1). (S2) is generated and transmitted to the remote management server, and the management server dispatches the administrator to the site where the specific event signal is generated so that it can take appropriate action to prevent the server from malfunctioning or crashing due to dust in an unexpected situation. Can be prevented.

In addition, the first and second compressed air generators interlock with the first and second dust detectors to measure and remove dust concentrations on a regular or irregular basis, thereby preventing dust from being excessively accumulated inside the first and second servers. Accordingly, the first and second servers can be operated in an optimal state.

1 is a view for explaining the overall configuration of a network control server management system according to the present invention,
2 is a view for explaining that the first and second server is installed in the first and second server rack of FIG.
3 is a side cross-sectional view for explaining the internal configuration of the first and second server rack and the first and second server of FIG.
4 is a block diagram illustrating a configuration of the first and second dust detection units of FIG. 3;
5 is a view for explaining the configuration of the first and second dust detection unit and the first and second compressed air injection unit installed in the first and second servers of FIG.

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

Hereinafter, what is described as "upper" or "upper" may include not only directly over and in contact but also overlying. Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. The terms are only used to distinguish one component from another. Singular expressions include plural expressions unless the context clearly indicates otherwise. In addition, when a part is said to "include" a certain component, which means that it may further include other components, except to exclude other components unless otherwise stated. In addition, the terms "...", "module", etc. described in the specification mean a unit that processes at least one function or operation.

1 is a view for explaining the overall configuration of the network control server management system according to the present invention, a view for explaining that the first and second server is installed in the first and second server rack of Figure 1 of FIG. 3 is a side cross-sectional view illustrating the internal configuration of the first and second server racks and the first and second servers of FIG. 2, and FIG. 4 is a block diagram illustrating the configuration of the first and second dust detection units of FIG. 5 is a view for explaining the configuration of the first and second dust detection unit and the first and second compressed air injection unit installed in the first and second servers of FIG.

As shown, the network control server management system according to the present invention includes a first server rack 20 on which a first server 10 for processing data is seated, and having a first identification code A1 for identification. ; A first dust detection unit 30 for detecting dust present in the first server 10; A first event signal generator 40 generating a first event signal S1 when the concentration of dust detected by the first dust detector 30 is equal to or higher than a set warning concentration; A first compressed air generator 50 installed in the first server rack 20 to generate compressed air; A first compressed air injection unit (60) for injecting compressed air generated by the first compressed air generation unit (50) into the first server (10); A second server rack 20 'on which the second server 10' for processing data is seated and having a second identification code A2 for identification; A second dust detector 30 ′ that detects dust accumulated in the second server 20 ′; A second event signal generator 40 'generating a second event signal S2 when the concentration of dust detected by the second dust detector 30' is equal to or higher than a set warning concentration; A second compressed air generating unit 50 'installed in the second server rack 20' to generate compressed air; A second compressed air injector 60 'which injects the compressed air generated by the second compressed air generator 50' into the second server 10 '; The first and second server racks 20 and 20 'are connected to the network N, and the first and second event signals S1 and S2 and the first and second identification codes A1 and A2 are connected to each other. Received management server 70; characterized in that it comprises a.

In the present embodiment, for the sake of easy description, only two servers are illustrated, but the number of the servers may be increased.

The first server 10 is installed inside the first server main body 11, and includes a plurality of first boards 12 including a CPU and a memory, a first storage device 13 such as a hard or SSD driver, and the like. It is implemented including a first power supply 14. The first server 10 is connected to a plurality of clients (computers) through a network (N) such as a LAN or the Internet, and shares file management, data processing, program support, a printer or a fax among clients.

The first server rack 20 is arranged in a specific place of an office or a factory and has a first identification code A1 for identification. The first server rack 20 includes a first rack body 21 supported on the ground, and a plurality of first shelves 22 provided with the first rack body 21.

The first dust detection unit 30 is for detecting dust existing in the first server 10, and as shown in FIGS. 3, 4, and 5, inside the first server body 11. The first sensing unit bracket 31 to be fixed, installed on one side of the first sensing unit bracket 31 of the first light emitting unit 32 for irradiating light (L), and the first sensing unit bracket 31 Partly shielded by the dust between the first light receiving part 33 and the first light emitting part 32 and the first light receiving part 33 provided on the other side and receiving the light L emitted from the first light emitting part 32. It includes a first concentration calculation unit 34 for calculating the dust concentration based on the change in the amount of light.

The first dust detection unit 30, the first light emitting unit 32, the first light receiving unit 33 and the first concentration calculation unit 34 are integrally formed on the first detection unit bracket 31 to form a single module. In this way, it is possible to easily install in the first server body (11).

The first event signal generator 40 generates the first event signal S1 and manages it through the network N when the dust concentration detected and calculated by the first dust detector 30 is equal to or greater than the set warning concentration. Transfer to server 70.

The first compressed air generating unit 50 is for generating high pressure compressed air to be sprayed into the first server 10, and as illustrated in FIG. 3, is installed in the first server rack 20 body. The first compression tank 51 filled with compressed air, the first compression pump 52 for supplying the high pressure air to the first compression tank 51, and the back of the first server rack 20 as It comprises a first duct 53 in communication with the first compression tank (51).

As shown in FIG. 3, the first compressed air injection unit 60 is installed on the first bracket 61 and the first bracket 61 fixed to the first server 10, and the first duct. The first distributor 62 in communication with the 53, the plurality of first distributor hoses 63 extending into the first server 10 as being connected to the first distributor 62, and the first distributor 62. ) And a first valve 64 installed between the first duct 53 and the first duct 53.

Here, the plurality of first distribution hoses 63 has a corrugated pipe shape so as to be variable in position in the first server 10, whereby the first distribution hoses 63 accumulate a lot of dust, that is, the first board. 12, the first storage device 13 and the first power supply 14 can be positioned opposite.

The first compressed air injector 60 instantaneously injects compressed air into the first server 10 to the first board 12, the first storage device 13, and the first power supply 14. The accumulated dust is instantaneously scattered, and thus the first dust detection unit 30 can detect the scattered dust.

The second server 10 'is installed inside the second server main body 11' and includes a plurality of second boards 12 'installed with a CPU and a memory, and a second storage device such as a hard or SSD driver. 13 ') and the second power supply 14 are embodied therein.

The second server rack 20 'is arranged at a specific place in an office or a factory and has a second identification code C2 for identification. The second server rack 20 'is composed of a second rack body 21' supported on the ground, and a plurality of second shelves 22 'provided with the second rack body 21. As shown in FIG.

The second dust detection unit 30 ′ is for detecting dust existing in the second server 10 ′. As shown in FIG. 4, the second dust detection unit 30 ′ is fixed inside the second server body 11 ′. 2 sensing unit bracket 31 ′, a second light emitting unit 32 ′ installed on one side of the second sensing unit bracket 31 ′ for irradiating light L, and a second sensing unit bracket 31 ′. Between the second light receiver 33 ′ and the second light receiver 32 ′ and the second light receiver 33 ′ provided at the other side of the second light receiver 32 ′ to receive the light L emitted from the second light emitter 32 ′. And a second concentration calculator 34 'that calculates a dust concentration based on a change in the amount of light partially shielded by the dust.

In the second dust detection unit 30 ', the second light emitting unit 32', the second light receiving unit 33 'and the second concentration calculating unit 34' are integrally formed on the second detection unit bracket 31 '. Therefore, one module is configured, and thus, the second server main body 11 'can be easily installed.

The second event signal generator 40 ′ generates the second event signal S1 when the dust concentration detected and calculated by the second dust detector 30 ′ is greater than or equal to the set warning concentration to generate the network N. It transmits to the management server 70 through.

The second compressed air generating unit 50 ′ is for generating high pressure compressed air to be injected into the second server 10 ′. As shown in FIG. 3, the second server rack 20 ′ main body is generated. A second compression tank 51 'installed at the second compressed tank 51' to supply compressed air, a second compression pump 52 'for supplying high pressure air to the second compression tank 51', and a second server rack 20 '. And a second duct 53 'which is installed at the rear surface of the bottom surface and communicates with the second compression tank 51'.

As shown in FIGS. 3, 4 and 5, the second compressed air injection unit 60 ′ includes a second bracket 61 ′ fixed to the second server 10 ′ and a second bracket 61. ') Is installed in the second distributor (62') in communication with the second duct (53 '), and a plurality of extending into the second server (10') connected to the second distributor (62 ') And a second valve 64 'and a second valve 64' installed between the second distributor 62 'and the second duct 53'.

Here, the plurality of second distribution hoses 63 'has a corrugated pipe shape so as to be variable in position inside the second server 10', and thus, a portion in which a large amount of dust is accumulated in the second distribution hoses 63 '. The second board 12 ′, the second storage device 13 ′, and the second power supply 14 ′ may be positioned to face each other.

The second compressed air injector 60 'instantaneously injects compressed air into the second server 10' to provide a second board 12 ', a second storage device 13' and a second power supply. The dust accumulated at 14 ′ is instantaneously scattered, and thus the second dust detection unit 30 ′ can detect scattered dust.

Here, the second compressed air injection unit 60 'repeatedly sprays compressed air for a predetermined time so that dust is continuously scattered inside the second server 10'. In this case, the scattered dust is discharged to the outside through a plurality of vents formed in the second server body 11 ', so that dust can be removed to some extent in the second server body 11'.

The management server 70 is connected to the first and second server racks 20 and 20 'by the network N. The first and second event signals S1 and S2 and the first and second identification codes ( A1) A2 is received.

By the above structure, when trying to detect the dust accumulated inside the first and second servers 10 and 10 ', the first and second compressed air injection units 60 and 60' instantaneously inject high pressure air. Instantaneously scatter dust accumulated on the first and second boards 12 and 12 ', the first and second storage devices 13 and 13', and the first and second power supplies 14 and 14 ', The scattered dust partially shields the light irradiated from the first and second light emitters 32 and 32 ', thereby changing the amount of light received by the first and second light emitters 33 and 33'. Then, the amount of light received by the first and second light receiving parts 33 and 33 'is changed, and the first and second concentration calculating parts 34 and 34' calculate the dust concentration D based on the light amount change. When the dust concentration D becomes equal to or higher than the set warning concentration, the first and second event signals S1 and S2 are generated.

The first and second event signals (S1) (S2) by the management server 60 to notify the administrator through the wired or wireless communication that the event situation occurred in the server of the remote server rack having a specific identification code, the event situation is Respond to the cause that occurred.

As described above, when the concentration of dust present inside the first and second servers 10 and 10 'is greater than or equal to the set warning concentration, the first and second dust detection units 30 and 30' detect this. The first and second event signal generators 40 and 40 ′ generate the first and second event signals S1 and S2 and transmit the generated first and second event signals S1 and S2 to the remote management server 70. By dispatching to the site where a specific event signal is generated, it is possible to prevent the malfunction or down of the server due to dust in an unexpected situation.

In addition, the first and second compressed air generators 50 and 50 'are interlocked with the first and second dust detectors 30 and 30' to measure and remove dust concentrations on a regular or irregular basis. It is possible to prevent excessive accumulation inside the first and second servers 10 and 10 ', thereby allowing the first and second servers to operate in an optimal state.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom.

10, 10 '... 1st, 2nd server 20, 20' ... 1st, 2nd server rack
21, 21 '... 1st, 2nd rack body 22, 22' ... 1st, 2nd shelf
30, 30 '... 1st, 2nd dust detection part 31,31' ... 1st, 2nd detection part bracket
32, 32 '... 1st, 2nd light emitting part 33, 33' ... 1st, 2nd light emitting part
34, 34 '... 1st, 2nd concentration calculator 40, 40' ... 1st, 2nd event signal generator
50, 50 '... first and second compressed air generating unit 51, 51' ... first and second compression tank
52, 52 '... 1st, 2nd compression pump 53, 53' ... 1st, 2nd duct
60, 60 '... 1, 2 compressed air jet 61, 61' ... 1, 2 bracket
62, 62 '... 1st, 2nd splitter 63, 63' ... 1st, 2nd split hose
64, 64 '... 1st, 2nd valve 70 ... Management server

Claims (7)

Installed in the first server 10 for data processing seated in the first server rack 20 having a first identification code (A1), to detect the dust accumulated excessively in the first server 10 First dust detection unit 30 for;
Dust that is excessively accumulated in the second server 10 'is installed inside the second server 10' for data processing mounted on the second server rack 20 'having the second identification code A2. A second dust detector 30 'for sensing;
A first event signal generator 40 generating a first event signal S1 when the concentration of dust detected by the first dust detector 30 is equal to or higher than a set warning concentration;
A second event signal generator 40 'generating a second event signal S2 when the concentration of dust detected by the second dust detector 30' is equal to or higher than a set warning concentration;
A first compressed air generating unit 50 installed in the first server rack 20 to generate compressed air;
A second compressed air generating unit 50 'installed in the second server rack 20' to generate compressed air;
First compressed air injection unit for instantaneously injecting the compressed air generated by the first compressed air generating unit 50 to the first server 10 in order to scatter the dust accumulated inside the first server 10 ( 60);
Second compressed air injection unit for injecting the compressed air generated by the second compressed air generating unit 50 'to the second server 10' in order to scatter the dust accumulated inside the second server 10 ' (60 '); And
The first and second server racks 20 and 20 'are connected to the network N by the first and second event signals S1 and S2 and the first and second identification codes A1 and A2. A management server 70 is received;
The first dust detection unit 30, the first detection unit bracket 31 is fixed to the inside of the first server body 11 of the first server 10 and the first detection unit bracket 31 The first light emitting part 32 is installed on one side and irradiates the light L, and the light L provided on the other side of the first sensing part bracket 31 is irradiated from the first light emitting part 32. A first concentration calculator 34 calculating a dust concentration based on a change in the amount of light partially shielded by dust between the receiving first light receiving unit 33 and the first light emitting unit 32 and the first light receiving unit 33; );
The second dust detection unit 30 'includes a second detection unit bracket 31' fixed inside the second server body 11 'of the second server 10' and the second detection unit bracket. A second light emitting part 32 'provided at one side of the 31' and irradiating light L, and a second light emitting part 32 'provided at the other side of the second sensing part bracket 31'. Dust on the basis of a change in the amount of light partially shielded by dust between the second light receiving portion 33 'and the second light receiving portion 32' and the second light receiving portion 33 'that receive the irradiated light L; A second concentration calculator 34 'that calculates the concentration;
The first light emitting unit 32 and the first light receiving unit 33 on the first detection unit bracket 31 so that the first dust detection unit 30 can be easily installed on the first server body 11. ) And the first concentration calculation unit 34 are integrated into one module;
The second light emitting part 32 'and the second light emitting part 32' on the second detecting part bracket 31 'can be easily installed on the second server main body 11'. And a second light receiver (33 ') and a second concentration calculator (34') are integrated into one module. delete delete The method of claim 1,
The first compressed air generating unit 50 is installed in the main body of the first server rack 20, the first compression tank 51 and the first compression tank 51, the compressed air is filled with high-pressure air A first compression pump 52 for supplying the first compression pump 52 and a first duct 53 installed on the rear surface of the first server rack 20 to communicate with the first compression tank 51;
The second compressed air generating unit 50 'includes a second compression tank 51' and a second compression tank 51 ', which are installed in the main body of the second server rack 20' and are filled with compressed air. The second compression pump 52 'which supplies the high pressure air to the furnace and the second duct 53' which is installed at the rear of the second server rack 20 'and communicates with the second compression tank 51' Network control server management system comprising: a. The method of claim 4, wherein
The first compressed air injection unit 60 is installed on the first bracket 61 and the first bracket 61 fixed to the first server 10 to communicate with the first duct 53. And a plurality of first distribution hoses (63) extending into the first server (10) as being connected to the first distributor (62);
The second compressed air injection unit 60 'is provided with a second bracket 61' fixed to the second server 10 'and the second duct 61'. 53 ') and a plurality of second distribution hoses 63' extending into the second server 10 'as being connected to the second distributor 62' and connected to the second distributor 62 '. Network control server management system comprising a. The method of claim 5,
The first compressed air injection unit (60) further includes a first valve (64) installed between the first distributor (62) and the first duct (53);
The second compressed air injection unit 60 'further includes a second valve 64' installed between the second distributor 62 'and the second duct 53'. Control Server Management System. The method of claim 5,
The first distribution hose (63) has a corrugated pipe shape to be variable in position inside the first server (10);
The second distribution hose (63 ') has a corrugated pipe shape to be variable in position inside the second server (10'); Network control server management system, characterized in that.

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