KR102030969B1 - Server management system using networks - Google Patents

Abstract

The present invention relates to a security server equipment management system using a network, which sprays compressed air into a server to prevent overheating. According to the present invention, the security server equipment management system using a network comprises first and second security server equipment (100, 200). The first security server equipment (100) comprises: a first server rack (220) having a first identification code (A1); a first dust detection unit (130) detecting dust existing in a first server (110); a first temperature measurement unit (140) measuring the internal temperature of the first server (110); and a first event signal generation unit (150) generating a first event signal (S1) when the concentration of the detected dust is equal to or greater than a set warning concentration or the measured temperature is equal to or greater than a set warning temperature. The second security server equipment (200) comprises: a second server rack (220) having a second identification code (A2); a second dust detection unit (230) detecting dust existing in a second server (210); a second temperature measurement unit (240) measuring the internal temperature of the second server (210); and a second event signal generation unit (250) generating a second event signal (S2) when the concentration of the detected dust is equal to or greater than the set warning concentration or the measured temperature is equal to or greater than the set warning temperature.

Description

Security server equipment management system using network {Server management system using networks}

The present invention relates to a security server equipment management system using a network, and more particularly, to a network server management system capable of detecting and appropriately responding to an event situation occurring in a specific server at a remote location.

In general, workplaces such as public institutions, companies, and hospitals operate security equipment 24 hours a day. The security equipment includes a large number of CCTV cameras, fingerprint or biometric scanners, and detection sensors that detect intrusions. It includes a security server that is directly and indirectly connected to a client through a network such as a LAN or a wired or wireless Internet. In a small workplace with tens of thousands of clients, all operations are possible with one security server. However, if the number of clients is hundreds or thousands, several security servers must be operated. Each security server is operated 24 hours a day. Process the data.

Security servers operating 24 hours a day generate a lot of heat from the CPU or memory when processing a lot of data in a certain situation, or if the place where the security server is installed is not well ventilated, or after midsummer weekend or after work If it stops, the security server is down due to overheating. In large-scale workplaces that operate multiple security servers, servers are installed and operated in data centers with constant temperature and humidity systems.

By the way, in the case of a small-scale operation of the security server, since there is practically no room to operate the data center, in general, the security server is deployed in a place where people do not have access well. In this case, when the place where the security server is disposed is a place where air is not smoothly ventilated, or when the air conditioner stops working after work in a hot season, the temperature of the security server may be excessively increased. In this case, despite the software security measures, a hardware failure occurred and eventually the security server was down.

In addition, because the security server operates 24 hours a day, the electromagnetic field is always generated inside the security server, which causes dust in the air to generate static electricity, which causes dust to accumulate in the security server over time. do. These dusts can cause parts to overheat due to static sparking in dry weather, destroying parts, and interfering with heat generation when accumulating on the CPU or memory, and in extreme cases, cause a fire due to dust explosion. An unsuccessful situation could cause the security server to crash or cause a fire.

As such, when the temperature of the security server is excessively increased or dust is accumulated inside the security server, a possibility of malfunction or down of the security server may occur, which may cause extreme confusion, and furthermore, the possibility of fire coexists.

The present invention has been created to solve the above problems, when the temperature of a specific security server excessively increased or excessive dust accumulation of a plurality of security servers installed in a remote site, the management server detects this event It aims to provide a security server equipment management system using a network that can take action so that the manager can be dispatched to the site.

Another object of the present invention is to provide a security server equipment management system using a network that can prevent overheating by measuring and removing dust concentrations periodically or irregularly in a server and by blowing compressed air into the server.

In order to achieve the above object, the security server equipment management system using a network according to the present invention, the first security server equipment 100 and the second security server equipment 200 that operates in a specific place, and the first , 2, which includes a management server 300 connected to a network with the security server equipment 100 and 200, wherein the first security server equipment 100 includes a first server rack having a first identification code A1 (A1). A first dust detection unit (130) installed in the first server (110) for data processing seated at 120, for detecting dust accumulated excessively in the first server (110); A first temperature measuring unit 140 measuring an internal temperature of the first server 110; When the dust detected by the first dust detection unit 130 is equal to or higher than the set warning concentration, or when the temperature measured by the first temperature measuring unit 140 is higher than the set warning temperature, the first event signal S1 is transmitted. Generating a first event signal generator 150; A first signal transmitter 160 for transmitting the first event signal S1 to the management server 300 through the network N; A first compressed air generating unit 170 installed in the first server rack 120 to generate compressed air; First compressed air injection unit 180 for injecting the compressed air generated by the first compressed air generating unit 170 to the first server 110 to scatter dust accumulated inside the first server 110. It includes; The second security server equipment 200 is installed in a second server 210 for data processing seated on a second server rack 220 having a second identification code A2, and the second server 210 is installed. A second dust detection unit 230 for detecting dust accumulated excessively inside; A second temperature measuring unit 240 measuring an internal temperature of the second server 210; When the dust detected by the second dust detection unit 230 is equal to or higher than the set warning concentration or when the temperature measured by the second temperature measuring unit 240 is higher than the set warning temperature, the second event signal S2 is output. Generating a second event signal generator 250; A second signal transmitter 260 for transmitting the second event signal S2 to the management server 300 through a network N; A second compressed air generator 270 installed in the second server rack 220 to generate compressed air; Second compressed air injection unit 280 for injecting the compressed air generated in the second compressed air generating unit 270 to the second server 210 in order to scatter dust accumulated inside the second server 210 in the mall It includes; The first dust detection unit 130 is installed on one side of the first bracket 131 fixed inside the first server body 111, the first light emitting unit 132 for irradiating light (L), A first light receiving unit 133 installed on the other side of the first bracket 131 to receive light L emitted from the first light emitting unit 132, and the first light emitting unit 132 and the first light receiving unit; A first concentration calculator 134 for calculating a dust concentration based on a change in the amount of light partially shielded by the dust between 133; The second dust detection unit 230 is installed on one side of the second bracket 231 fixed inside the second server body 221 and the second light emitting unit 232 for irradiating light (L), A second light receiving unit 233 installed on the other side of the second bracket 231 to receive light L emitted from the second light emitting unit 232, and the second light emitting unit 232 and the second light receiving unit; A second concentration calculator 234 for calculating a dust concentration based on a change in the amount of light partially shielded by the dust between 233; The first light emitting unit 132, the first light receiving unit 133, on the first bracket 131 so that the first dust detection unit 130 can be easily installed on the first server body 111. The first concentration calculating unit 134 and the first dust warning signal generating unit 135 are integrated into one module; The second light emitting unit 232 and the second light receiving unit 233 on the second bracket 231 so that the second dust detection unit 230 can be easily installed in the second server body 221. ), The second concentration calculator 234 and the second dust warning signal generator 235 are integrated into one module; The first temperature measuring unit 140 is supported by a first bracket 141 installed in the first server main body 111, the first wire bracket (1) that can be changed in position within the first server main body (111) 142 and a first infrared sensor 143 supported at the tip of the first wire bracket 142; The second temperature measuring unit 240 is supported by a second bracket 241 installed in the second server main body 211, the second wire bracket (2) which can be changed in position inside the second server main body 211 ( 242 and a second infrared sensor 243 supported at the tip of the second wire bracket 242.
In the present invention, the first dust detection unit 130, the first dust warning signal generating unit 135 for generating a first dust warning signal (DS1) when the calculated dust concentration is more than the set warning concentration. More; The second dust detection unit 230 further includes a second dust warning signal generator 235 for generating the first dust warning signal DS1 when the calculated dust concentration is equal to or higher than the set warning concentration.

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In the present invention, the first temperature measuring unit 140, the first overheat signal for generating a first overheat warning signal TS1 when the temperature measured by the first infrared sensor 143 is higher than the set warning temperature A generator 144 further; The second temperature measuring unit 240 generates a second overheat warning signal TS2 when the temperature measured by the second infrared sensor 243 is higher than a set warning temperature. It further includes.

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In the present invention, the first compressed air generating unit 170 is installed in the body of the first server rack 120, the first compression tank 171 and the compressed air is filled, and the first compression tank 171 And a first compression pump 172 for supplying high pressure air to the air, and a first duct 173 installed on a rear surface of the first server rack 120 to communicate with the first compression tank 171. and; The second compressed air generating unit 270 is installed in the second server rack 220 main body and filled with compressed air to the first compression tank 271 and the second compression tank 271 to the high-pressure air It includes a second compression pump 272 for supplying the second duct 273, which is installed on the back of the second server rack 220 and communicates with the second compression tank (271).

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In the present invention, the first compressed air injection unit 180 is installed in the first bracket 181 and the first bracket 181, which is fixed to the position of the first server 110, the first bracket A first distributor (182) in communication with the duct (173) and a plurality of first distributor hoses (183) extending into the first server (110) as being connected to the first distributor (182); The second compressed air injection unit 280 is provided with a second bracket 281 fixed to the second server 210 and the second bracket 281 and the second duct 273. The second distributor 282 communicates with the second distributor 282 and includes a plurality of second distributor hoses 283 extending into the second server 210.

According to the present invention, the concentration of dust detected by the first and second dust detectors inside the first and second servers is equal to or higher than the set warning concentration, or the temperature measured by the first and second temperature measuring units is higher than the set warning temperature. In this case, the first and second event signal generators generate the first and second event signals S1 and S2 and transmit them to a remote management server, and the management server dispatches an administrator to a site where a specific event signal is generated and responds appropriately. By doing so, you can prevent the server from malfunctioning or crashing due to dust under unforeseen circumstances.

In addition, the first and second compressed air generating unit is interlocked with the first and second dust detection unit to measure and remove the dust concentration on a regular or irregular basis, thereby preventing excessive accumulation of dust inside the first and second servers. Accordingly, the first and second servers can be operated in an optimal state.

In addition, since the compressed air injected to the first and second servers can be cooled by the first and second air cooling units, when the data processing amount is excessive, the compressed air cooled to the first and second servers is periodically or irregularly sprayed. By doing so, the first and second servers can be operated in an optimal state without being down.

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

Hereinafter, a security server equipment management system using a network 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 security server equipment management system using a network according to the present invention, Figure 2 is a block diagram illustrating the configuration of the first and second security server equipment of Figure 1, 3 is a side cross-sectional view for explaining the configuration of the first and second security server equipment of FIG. 4 is a diagram for explaining the configuration of the first and second dust detection unit of Figure 2, Figure 5 is a diagram for explaining the configuration of the first, second temperature measuring unit of Figure 2, Figure 6 The first and second dust detectors, the first and second temperature measuring units, and the first and second compressed air jetting units provided in the first and second servers of the present article 3 are for explaining the configuration.

As shown, the security server equipment management system using the network according to the present invention, the first security server equipment 100 and the second security server equipment 200 that is operated in a specific place, and the first and second security server equipment It includes a management server 300 connected to the network (100) (200).

In the present embodiment, for the sake of easy description, the security server equipment is limited to two, but the number of the security server equipment may be increased.

The first security server device 100, through a LAN or wired / wireless network with a client (not shown) such as a plurality of CCTV cameras, fingerprints or biometrics, detection sensors that detect intrusions, which are operated 24 hours a day at a specific workplace. It is connected directly or indirectly. The first security server device 100, the first server 110 for processing various data transmitted from the client is seated, the first server rack 120 having a first identification code (A1) for identification and; A first dust detection unit 130 for detecting dust present in the first server 110; A first temperature measuring unit 140 measuring an internal temperature of the first server 110; When the dust detected by the first dust detection unit 130 is equal to or higher than the set warning concentration or when the temperature measured by the first temperature measuring unit 140 is higher than the set warning temperature, the first event signal S1 is generated. A first event signal generator 150; A first signal transmitter 160 for transmitting the first event signal S1 to the management server 300 through the network N; A second compressed air generator 170 installed in the first server rack 120 to generate compressed air; A first compressed air injection unit 180 for injecting compressed air generated by the first compressed air generation unit 160 into the first server 110; And a first air cooling unit 190 installed between the first compressed air generation unit 170 and the first compressed air injection unit 180 to cool the compressed air.

The first server 110 is installed inside the first server body 111, and includes first data such as a first board 112, a hard or SSD driver, on which a related component such as a CPU 112a for processing data is mounted. The storage device 113 includes a first power supply 114 for supplying power. The first server 110 is connected to a client such as a CCTV camera, a fingerprint or biometric reader, a detection sensor for detecting an intrusion through the network (N).

The first server rack 120 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 120 is composed of a first rack body 121 supported on the ground, and a plurality of first shelves 122 provided with the first rack body 121.

The first dust detection unit 130 is for detecting dust existing in the first server 110, and as shown in FIGS. 3, 4, and 6, inside the first server body 111. The first light emitting unit 132 is installed on one side of the fixed first bracket 131 and irradiates the light L, and is installed on the other side of the first bracket 131 to be irradiated from the first light emitting unit 132. A first concentration calculation based on a change in the amount of light partially shielded by dust between the first light receiving unit 133 that receives the light L and the first light receiving unit 132 and the first light receiving unit 133. A concentration calculation unit 134 and a first dust warning signal generator 135 for generating the first dust warning signal DS1 when the calculated dust concentration is equal to or higher than the set warning concentration are included.

The first dust detector 130 may include a first light emitter 132, a first light receiver 133, a first concentration calculator 134, and a first dust warning signal generator 135 on the first bracket 131. ) Is integrated into one module, and thus can be easily installed in the first server main body 111.

The first temperature measuring unit 140, as shown in Figures 3, 4 and 6. The first wire bracket 142 and the front end of the first wire bracket 142 supported by the first bracket 141 installed on the first server main body 111 and capable of changing its position in the first server main body 111. A first overheat warning signal generator 144 for generating a first overheat warning signal TS1 when the temperature measured by the first infrared sensor 143 and the first infrared sensor 143 is higher than the set warning temperature; ).

When the dust detected by the first dust detector 130 becomes greater than or equal to the set warning concentration, or the temperature measured by the first temperature measuring unit 140 is higher than the set warning temperature, the first event signal generator 150 is higher. The first event signal S1 is generated. That is, when dust is excessively accumulated in the first server 110 so that the concentration of dust becomes more than the warning concentration, or when the temperature of the first board 112 becomes overheated and becomes more than the warning temperature, the first event situation is different from usual. In this case, the first event signal generator 150 generates the first event signal.

The first signal transmitter 160 transmits the first event signal S1 to the management server 300 through the network N.

The first compressed air generating unit 170 is for generating a high pressure compressed air to be injected into the first server 110, as shown in Figure 3, is installed in the main body of the first server rack 120 It is installed on the back of the first compression tank 171 filled with compressed air, the first compression pump 172 for supplying high pressure air to the first compression tank 171, and the first server rack 120 The first duct 173 communicates with the first compression tank 171.

As shown in FIG. 3, the first compressed air injection unit 180 is installed on the first bracket 181 fixed to the first server 110 and the first bracket 181 as the first bracket 181. The first distributor 182 in communication with the duct 173, the plurality of first distributor hoses 183 extending into the first server 110 and connected to the first distributor 182, and the first distributor ( The first valve 184 is installed between the 182 and the first duct 173.

Here, the plurality of first distribution hoses 183 has a corrugated pipe shape so as to be variable in position in the first server 110, and thus, the first distribution hose 183 has a lot of dust, that is, the first board 112, the first storage device 113 and the first power supply 114 may be positioned to face each other. The first compressed air injection unit 180 instantaneously sprays compressed air into the first server 110 to the first board 112, the first storage device 113, and the first power supply 114. The accumulated dust is instantaneously scattered, so that the first dust detector 130 can detect the scattered dust.

Here, the first compressed air injection unit 180 repeatedly sprays compressed air for a set time so that dust is continuously scattered inside the first server 110. In this case, the scattered dust is discharged to the outside through a plurality of vents formed in the first server body 111, it is possible to remove the dust to some extent in the first server body 111.

As illustrated in FIG. 3, the first air cooling unit 190 is for cooling the compressed air supplied to the first compressed air generating unit 170. The first air cooling unit 190 includes a first air conditioning tank 191 installed in the first conduit 171a between the first compressed air generating unit 170 and the first compressed air injection unit 180. , Which is installed in the first air conditioning tank 191, adheres to the first cooling block 192 and the first cooling block 192 having a plurality of first cooling fins 192a for increasing a contact area with air. The first thermoelectric element 193 having the first cooling surface 193a to be in contact with the first heat dissipating surface 193b of the first thermoelectric element 193, and a plurality of first elements for increasing the contact area with air. The first heat dissipation block 194 having the heat dissipation fins 194a and a first heat dissipation fan 195 installed in the first heat dissipation block 194 to induce the flow of air to the first heat dissipation fin 194a are included.

When power is applied to the first thermoelectric element 193 by the first air cooling unit 190, heat is generated from the first cooling surface 193a to the first heat dissipating surface 193b, and thus The first cooling fins 192a of the first cooling block 192 absorb heat of ambient air and radiate heat to the first heat sink fins 194a of the first heat radiation block 194.

In this case, the first air conditioning tank 191 forms a larger space than the first pipe line 171a, and the first air conditioning tank 191 has a plurality of first cooling fins 192a installed therein. The air passing through 171a is momentarily cooled while passing between the plurality of first cooling fins 192a having a large contact surface, and then injected into the first server 110 through the first compressed air injection unit 180. do.

That is, since the compressed air cooled to the inside of the first server 110 may be injected as necessary, the first server 110 may not be shut down by cooling related components such as the CPU 112a in a special situation in which data processing is excessive. Can be driven without.

The second security server device 200, which is operated in a space that is far from the first security server device 100, detects a plurality of CCTV cameras, fingerprints or biometrics, and intrusions operated 24 hours a day at a specific workplace. It is directly or indirectly connected to a client (not shown) such as a detection sensor through a LAN or a wired / wireless network. The second security server device 200, the second server 210 for processing various data transmitted from the client is seated, the second server rack 220 having a second identification code (A2) for identification and; A second dust detector 230 for detecting dust present in the second server 210; A second temperature measuring unit 240 measuring an internal temperature of the second server 210; When the dust detected by the second dust detection unit 230 is equal to or higher than the set warning concentration, or when the temperature measured by the second temperature measuring unit 240 is higher than the set warning temperature, the second event signal S2 is generated. A second event signal generator 250; A second signal transmitter 260 for transmitting the second event signal S2 to the management server 300 through the network N; A second compressed air generator 270 installed in the second server rack 220 to generate compressed air; And a second compressed air injection unit 280 for injecting compressed air generated by the second compressed air generation unit 270 into the second server 210.

The second server 210 is installed inside the second server main body 211 and includes second data such as a second board 212, a hard or SSD driver, on which a related component such as a CPU 212a for processing data is mounted. The storage device 213 includes a second power supply 214 for supplying power. The second server 210 is connected to a client such as a CCTV camera, a fingerprint or biometric reader, a detection sensor for detecting an intrusion through the network (N).

The second server rack 220 is disposed in a specific place of an office or a factory and has a second identification code A2 for identification. The second server rack 220 is composed of a second rack body 221 supported on the ground, and a plurality of second shelves 222 provided with the second rack body 221.

The second dust detection unit 230 is for detecting dust existing in the second server 210, and as shown in FIGS. 3, 4, and 6, inside the second server body 211. The second light emitting unit 232 is installed on one side of the fixed second bracket 231 and irradiates the light (L), and is installed on the other side of the second bracket 231 is irradiated from the second light emitting unit 232 A second concentration calculation based on a change in the amount of light partially shielded by dust between the second light receiving unit 233 that receives the light L and the second light receiving unit 232 and the second light receiving unit 233. A concentration calculation unit 234 and a second dust warning signal generator 235 for generating a second dust warning signal DS1 when the calculated dust concentration is equal to or higher than the set warning concentration are included.

The second dust detector 230 may include a second light emitter 232, a second light receiver 233, a second concentration calculator 234, and a second dust warning signal generator 235 on the second bracket 231. ) Is integrated into one module, and thus can be easily installed on the second server main body 211.

As shown in FIGS. 3, 4, and 6, the second temperature measuring unit 240 is supported by a second bracket 241 installed on the second server main body 211, so that the second server main body 211 is supported. The second wire bracket 242 which can be changed in position, the second infrared sensor 243 supported at the tip of the second wire bracket 242, and the temperature measured by the second infrared sensor 243 are set. The second overheat warning signal generator 244 generates a second overheat warning signal TS2 when the temperature is higher than the temperature.

When the dust detected by the second dust detector 230 is greater than or equal to the set warning concentration, or when the temperature measured by the second temperature measuring unit 240 is higher than the set warning temperature, the second event signal generator 250 is higher. The second event signal S2 is generated. That is, when dust is excessively accumulated in the second server 210 and the concentration of dust becomes more than the warning concentration, or when the temperature of the second board 212 becomes over the warning temperature, it becomes a second event situation different from usual. In this case, the second event signal generator 250 generates the second event signal.

The second signal transmitter 260 transmits the second event signal S2 to the management server 300 through the network N.

The second compressed air generating unit 270 is for generating high pressure compressed air to be sprayed into the second server 210, as shown in FIG. 3, and installed in the second server rack 220 main body. The second compression tank 271 filled with the compressed air, the second compression pump 272 for supplying high pressure air to the second compression tank 271, and the second server rack 220 is provided on the back And a second duct 273 in communication with the second compression tank 271.

As shown in FIG. 3, the second compressed air injection unit 280 is installed on the second bracket 281 and the second bracket 281, which are fixed to the second server 210. A second distributor 282 communicating with the duct 273, a plurality of second distributor hoses 283 extending into the second server 210 as being connected to the second distributor 282, and a second distributor ( 282 and a second valve (284) is provided between the second duct (273).

Here, the plurality of second distribution hoses 283 has a corrugated pipe shape so that the position of the second distribution hoses 283 may be variable inside the second server 210. Accordingly, the second distribution hoses 283 have a large amount of dust, namely, a second board. 212, the second storage device 213, and the second power supply 214 may be positioned to face each other.

The second compressed air injection unit 280 instantaneously sprays compressed air into the second server 210 to the second board 212, the second storage device 213, and the second power supply 214. The accumulated dust is instantaneously scattered, so that the second dust detector 230 can detect the scattered dust.

Here, the second compressed air injection unit 280 repeatedly sprays compressed air for a set time so that dust is continuously scattered inside the second server 210. In this case, the scattered dust is discharged to the outside through a plurality of vents formed in the second server body 210, it is possible to remove the dust to some extent in the second server body 211.

As shown in FIG. 3, the second air cooling unit 290 is for cooling the compressed air supplied to the second compressed air generating unit 270. The second air cooling unit 290 includes a second air conditioning tank 291 provided in the first conduit 271a between the second compressed air generating unit 270 and the second compressed air injection unit 280. , Which is installed in the second air conditioning tank 291, adheres to the second cooling block 292 and the second cooling block 292 having a plurality of second cooling fins 292a to increase the contact area with air. The second thermoelectric element 293 having the second cooling surface 293a to be in contact with the second heat dissipating surface 293b of the second thermoelectric element 293, and a plurality of second to increase the contact area with air. The second heat dissipation block 294 having the heat dissipation fins 294a and a second heat dissipation fan 295 installed in the second heat dissipation block 294 to guide the flow of air to the second heat dissipation fins 294a are included.

When power is applied to the second thermoelectric element 293 by the second air cooling unit 290, heat is generated from the second cooling surface 293a to the second heat dissipating surface 293b, and accordingly, The second cooling fin 292a of the second cooling block 292 absorbs heat of ambient air and radiates heat to the second heat dissipation fin 294a of the second heat dissipation block 294.

At this time, since the second air conditioning tank 291 has a larger space than the second conduit 271a, and the second air conditioning tank 291 is provided with a plurality of second cooling fins 292a, the second conduit The air passing through the 271a is instantaneously cooled while passing between the plurality of second cooling fins 292a having a large contact surface, and then injected into the second server 210 through the second compressed air jet 280. do.

That is, since the compressed air cooled to the inside of the second server 210 can be injected as necessary, the second server 210 is not brought down by cooling the related components such as the CPU 212a in a special situation in which data processing is excessive. Can be driven without.

The management server 300 is connected by the first and second server racks 120 and 220 and the network N, and includes 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 the dust accumulated in the first and second servers 110 and 210 is to be detected, the first and second compressed air injection units 180 and 280 instantaneously inject high pressure air to make the first dust. The dust accumulated by the first and second boards 112 and 212, the first and second storage devices 113 and 213, and the first and second power supplies 114 and 214 is instantaneously scattered, The amount of light received by the first and second light receiving units 133 and 233 is changed by partially shielding the light emitted from the first and second light emitting units 132 and 232. Then, the amount of light received by the first and second light receiving units 133 and 233 is changed, and the first and second concentration calculating units 134 and 234 calculate the dust concentration based on the light amount change, and the dust concentration is set. When the concentration is equal to or greater than the first and second event signals S1 and S2 are generated.

The first and second event signals (S1) (S2) by the management server 300 to notify the administrator through the wired and wireless communication that the event situation has 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, according to the present invention, the concentration of dust detected by the first and second dust detectors 130 and 230 inside the first and second servers 110 and 210 is equal to or higher than the set warning concentration, When the temperature measured by the second temperature measuring unit 140 or 240 is higher than the set warning temperature, the first and second event signal generators 150 and 250 may generate the first and second event signals S1 and S2. It occurs and transmits to the remote management server 300, the management server 300 dispatches the administrator to the site where a specific event signal is generated, so that appropriate action can be taken to prevent the malfunction of the server due to dust in an unexpected situation or The down can be prevented.

In addition, the first and second compressed air generators 170 and 270 are interlocked with the first and second dust detectors 130 and 230 to measure and remove dust concentrations on a regular or irregular basis. Excessive accumulation inside the two servers 110 and 210 may be prevented and thus the first and second servers may be operated in an optimal state.

In addition, since the compressed air injected into the first and second servers 110 and 210 by the first and second air cooling units 190 and 290 may be cooled, when the amount of data processing is excessive, periodically or irregularly. By spraying the compressed air cooled by the first and second servers 110 and 210, the first and second servers 110 and 210 may be optimally driven without being down.

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.

110, 210 ... 1,2 server 120, 220 ... 1,2 server rack
121, 221 ... 1st, 2nd rack body 122, 222 ... 1st, 2nd shelf
130, 230 ... first, second dust detection unit 131, 231 ... first, second bracket
132, 232 ... 1st, 2nd light emitting part 133, 233 ... 1st, 2nd light emitting part
134, 234 ... 1st, 2nd concentration calculator 140, 240 ... 1st, 2nd temperature measuring part
142, 242 ... 1, 2 wire bracket 143, 243 ... 1, 2 infrared sensor
144, 244 ... first and second overheat warning signal generator
150, 250 ... first and second event signal generator
160, 260 ... first and second signal transmitter 170, 270 ... first and second compressed air generator
171, 271 Compression tanks 172, 272 Compression pumps 272, 272
173, 273 ... 1st, 2nd duct 180, 280 ... 1st, 2nd compressed air jet
182, 282 ... 1st, 2nd distributor 183, 283 ... 1st, 2nd distribution hose
184, 284 ... 1,2 valves 190, 290 ... 1,2 air coolers
191, 291 ... 1st, 2nd air conditioning tanks 192, 292 ... 1st, 2nd cooling block
192a, 292a ... first and second cooling fins 193, 293 ... first and second thermoelectric elements
194, 294 ... 1st, 2nd heat radiation blocks 194a, 294a ... 1st, 2nd heat radiation fins
195, 295 ... 1st, 2nd radiating fan 300 ... management

Claims (8)

The first security server equipment 100 and the second security server equipment 200 that operates in a specific place, and the first and second security server equipment 100, including a management server 300 connected to the network by the network As,
The first security server equipment 100 is installed inside the first server 110 for data processing seated on the first server rack 120 having the first identification code A1, and the first server ( 110, the first dust detection unit 130 for detecting the dust accumulated excessively inside; A first temperature measuring unit 140 measuring an internal temperature of the first server 110; When the dust detected by the first dust detection unit 130 is equal to or higher than the set warning concentration, or when the temperature measured by the first temperature measuring unit 140 is higher than the set warning temperature, the first event signal S1 is transmitted. Generating a first event signal generator 150; A first signal transmitter 160 for transmitting the first event signal S1 to the management server 300 through the network N; A first compressed air generating unit 170 installed in the first server rack 120 to generate compressed air; First compressed air injection unit 180 for injecting the compressed air generated by the first compressed air generating unit 170 to the first server 110 to scatter dust accumulated inside the first server 110. It includes;
The second security server equipment 200 is installed in a second server 210 for data processing seated on a second server rack 220 having a second identification code A2, and the second server 210 is installed. A second dust detection unit 230 for detecting dust accumulated excessively inside; A second temperature measuring unit 240 measuring an internal temperature of the second server 210; When the dust detected by the second dust detection unit 230 is equal to or higher than the set warning concentration or when the temperature measured by the second temperature measuring unit 240 is higher than the set warning temperature, the second event signal S2 is output. Generating a second event signal generator 250; A second signal transmitter 260 for transmitting the second event signal S2 to the management server 300 through a network N; A second compressed air generator 270 installed in the second server rack 220 to generate compressed air; Second compressed air injection unit 280 for injecting the compressed air generated by the second compressed air generating unit 270 to the second server 210 in order to scatter dust accumulated inside the second server 210 in the mall It includes;
The first dust detection unit 130 is installed on one side of the first bracket 131 fixed inside the first server body 111, the first light emitting unit 132 for irradiating light (L) and the The first light receiving unit 133 is installed on the other side of the first bracket 131 and receives the light L emitted from the first light emitting unit 132, and the first light emitting unit 132 and the first light receiving unit ( A first concentration calculator 134 for calculating a dust concentration based on a change in the amount of light partially shielded by the dust between 133;
The second dust detection unit 230 is installed on one side of the second bracket 231 fixed inside the second server body 221 and the second light emitting unit 232 for irradiating light (L) and the A second light receiving unit 233 installed on the other side of the second bracket 231 to receive the light L emitted from the second light emitting unit 232, the second light emitting unit 232, and a second light receiving unit ( A second concentration calculator 234 for calculating a dust concentration based on a change in the amount of light partially shielded by the dust between 233;
The first light emitting unit 132, the first light receiving unit 133, on the first bracket 131 so that the first dust detection unit 130 can be easily installed on the first server body 111. The first concentration calculating unit 134 and the first dust warning signal generating unit 135 are integrated into one module;
The second light emitting unit 232 and the second light receiving unit 233 on the second bracket 231 so that the second dust detection unit 230 can be easily installed in the second server body 221. ), The second concentration calculator 234 and the second dust warning signal generator 235 are integrated into one module;
The first temperature measuring unit 140 is supported by a first bracket 141 installed in the first server main body 111, the first wire bracket (1) that can be changed in position within the first server main body (111) 142 and a first infrared sensor 143 supported at the tip of the first wire bracket 142;
The second temperature measuring unit 240 is supported by a second bracket 241 installed in the second server main body 211, the second wire bracket (2) which can be changed in position inside the second server main body 211 ( 242) and a second infrared sensor (243) that is supported at the tip of the second wire bracket (242). delete The method of claim 1,
The first dust detection unit 130 further includes a first dust warning signal generation unit 135 for generating a first dust warning signal DS1 when the calculated dust concentration is equal to or higher than a set warning concentration;
The second dust detection unit 230 further includes a second dust warning signal generator 235 for generating a first dust warning signal DS1 when the calculated dust concentration is equal to or higher than a set warning concentration; Security server equipment management system using a network characterized in that. delete The method of claim 1,
The first temperature measuring unit 140 generates a first overheat warning signal TS1 when the temperature measured by the first infrared sensor 143 is higher than a preset warning temperature. Further comprising;
The second temperature measuring unit 240 generates a second overheat warning signal TS2 when the temperature measured by the second infrared sensor 243 is higher than a set warning temperature. Security server equipment management system using a network, characterized in that it further comprises; delete The method of claim 1,
The first compressed air generating unit 170 is installed in the body of the first server rack 120, the first compression tank 171 and the compressed air is filled with the high pressure air to the first compression tank (171) A first compression pump (172) for supplying the first compression pump (172) and a first duct (173) which is installed on the rear surface of the first server rack (120) and communicates with the first compression tank (171);
The second compressed air generating unit 270 is installed in the second server rack 220 main body, the second compression tank (271) filled with compressed air and the second compressed tank 271 to the high-pressure air The second compression pump 272 for supplying a second, and the network is characterized in that it comprises a second duct (273) which is installed on the back of the second server rack 220 and in communication with the second compression tank (271) Security server equipment management system using. The method of claim 7, wherein
The first compressed air injection unit 180 is installed on the first bracket 181 fixed to the first server 110, the first duct 173 and the first duct 173 and A first distributor 182 communicating therewith and a plurality of first distributor hoses 183 extending into the first server 110 as being connected to the first distributor 182;
The second compressed air injection unit 280 is installed on the second bracket 281 and the second bracket 281 fixed to the second server 210 and the second duct 273. A second distributor 282 communicating therewith and a plurality of second distributor hoses 283 extending into the second server 210 as being connected to the second distributor 282. Security server equipment management system using.

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