KR101547869B1 - Emp protection rack - Google Patents

Abstract

The present invention relates to an EMP protection rack which is formed in a completely sealed structure to prevent dust from entering thereinto, and has a constant temperature and humidity function, an emergency protection function for handling heating by an abnormal high temperature or the like, a fire detecting and extinguishing function, a remote control function, etc. The EMP protection rack (R) comprises a rack case (1) in which computation equipment is mounted and a door (10) mounted on a front surface of the rack case (1) to open and close. The EMP protection rack further comprises: a case room (13) which is formed on a lower portion of the rack case (1), and wherein a constant temperature and humidity module (3) can be mounted thereon and detached therefrom; and the constant temperature humidity module (3) which comprises an internal air circulation duct (4) to maintain a constant temperature and humidity by cooling/heating air inside the rack case (1) and an external air circulation duct (8) to radiate refrigerant condensation heat of the internal air circulation duct (4) contributing to the constant temperature and humidity which are separated by a partitioning wall (31) and embedded therein, is formed in a box having a cover (33) mounted on an upper portion thereof, and slidably and detachably mounted on the case room (13) disposed on the lower portion of the rack case (1).

Description

EMP Protection Rack {EMP PROTECTION RACK}

The present invention relates to an EMP protection rack, and more particularly, to an EMP protection rack having a completely sealed structure to prevent inflow of dust into the inside of the EMP protection rack, and to provide an emergency protection function against heat generated by abnormal temperature and humidity, A fire detection and fire extinguishing function, and a remote control function.

In modern society, most of the tasks in defense, finance, and control are processed through computerization, electronics, communication, computer equipment, etc., and these systems are destroyed and damaged by external artificial or natural causes. If the damage is serious, it will cause serious consequences beyond imagination. Therefore, various attempts are being actively made to strengthen security and invest in security facilities to prevent such damage.

Particularly, electromagnetic pulse (hereinafter referred to as EMP) refers to an electromagnetic energy generated naturally by lightning or by artificially generated by an electronic bomb. EMP by such an electronic bomb causes high microwave energy in an instant And disruption of computer, electronic, communication, and computer equipment, damaging and destroying the national defense information system, the administrative computer system, and the financial information system.

Accordingly, various protection facilities and technologies are being developed to protect the hardware components such as the server, the network equipment for communicating with the computer, and the data storage from the EMP, which implements the main functions of the information communication system business processing.

First, some examples of EMP protection facilities are as follows;

References 1; A honeycomb panel for shielding is provided in a clearance formed in an outer wall assembly portion and a ventilator and an opening portion of a shelter box for protecting equipment from electromagnetic waves and a shield box for electromagnetic wave shielding can be shielded from electromagnetic waves penetrating through them. References 2; There is disclosed a ventilation hole having a shielding function for preventing disturbance and failure of an electronic device by a strong electromagnetic pulse generated by the explosion of a nuclear bomb or an electronic bomb while preventing eavesdropping by electromagnetic waves due to electromagnetic wave emission.

In Reference 4, It protects and protects electronic equipments, communication equipments and financial systems that require national security, national defense, financial protection by preventing electromagnetic pulses or high electromagnetic pulses from flowing into the inside, An EMC protection room is disclosed.

Also, in Reference 7; There is disclosed an EMP shutoff vent which allows a high frequency electromagnetic wave to be shielded by a ventilation pipe provided with the mesh by providing a mesh in the ventilation pipe and connecting it to the shielded chamber.

As described in the above references, since it takes a great deal of time and money to install a whole building as a customized EMP protection, a method of mounting a server network and computer equipment in an EMP protection rack is more preferred. Let's look at some typical examples.

References 3; EMP protection cabinet to prevent paralysis or permanent destruction of electronic equipment such as communication equipment, computer server, etc., in which electromagnetic pulses are introduced into the circuit of electronic equipment by power line or various signal lines, .

In Reference 5, An exhaust unit having an exhaust pipe having an electromagnetic pulse passage suppressing structure and an exhaust fan, an EMP for electromagnetic pulse shielding, a chamber body to which a power line with an electromagnetic wave filter is applied, an intake unit having an intake pipe and an intake fan, A connector having a limiter, an antenna connection unit having an electromagnetic pulse passage suppression structure, and the like.

Also, in Reference 6; A first enclosure of the magnetic metal on which the electrical equipment is mounted, a second enclosure which is constructed in an insulated state into which the first enclosure is inserted, and a second enclosure which is disposed between the first enclosure and the second enclosure to insulate the first enclosure from the second enclosure An insulating spacer and the like to double-shield the lightning and the induction magnetic field of the electromagnetic wave.

Also, in Reference 8; Electromagnetic wave shielding vents respectively formed on a wall surface of a plurality of galvanized steel sheets, an upper surface of a rear surface and a ceiling surface, front and rear doors that can be opened and closed, grounding means connected to an outer frame from a wall surface or a bottom surface, An EMP protection cabinet constituted by a shielded ventilator is disclosed.

Also, in Reference 9; A rack frame forming a frame of a hexahedron forming an internal device accommodation space; A protective panel formed of a conductive material and coupled to each surface of the rack frame and having a coupling groove; And a reinforcing member coupled to the coupling groove of the protection panel.

Although the EMP protection rack disclosed in the above references has implemented the purpose of shielding EMP in various ways for shielding, it is not necessary to completely prevent the EMP protection due to the heat generated in operation of the equipment installed in the rack, As the temperature inside the shielded rack suddenly increases, the stable operation of the computer equipment installed in the rack can not be guaranteed.

Accordingly, the existing EMP protection rack is structured to circulate the internal air by installing an external air inlet and an exhaust fan in the protection rack to prevent malfunction and malfunction due to the temperature rise of the equipment inside the rack.

However, this method is a structure in which the computer network devices including the server can not be exposed to the dust inflow from the outside and can not provide stable temperature / humidity maintenance. In the end, EMP protection racks are a very inefficient investment that leads to breakdowns and shutdown of computing and network equipment due to dust entry and lack of constant temperature and humidity functions.

Therefore, it was necessary to construct the EMP protection rack with a perfect airtight structure and to provide a constant temperature and humidity function for stable operation under such a perfect airtight structure so as to block the inflow of external dust.

On the other hand, even if it has the constant temperature and humidity function for optimum efficiency and stable operation, if the constant temperature and humidity function does not operate properly due to power failure or other causes, or if the internal temperature rises due to the internal heat, the server installed in the EMP protection rack, Computing equipment suffers from catastrophic problems such as shutdown or damage.

Accordingly, in addition to the above-mentioned constant temperature and humidity function, when an abnormally high temperature is generated at a certain temperature or more, the outside air is forcedly drawn into the room and the internal temperature is lowered so that the computer equipment can be operated normally Emergency protection devices are also required.

In addition, it is equipped with emergency protection against high temperature due to heat load and malfunction of server, computer equipment installed inside and equipped with constant temperature and humidity function, but there are other various factors such as fire and smoke inside EMP protection rack It can not be excluded at all. Such a fire causes a serious problem to the server and the computer equipment, and there is a fear that the fire spreads to the whole room where the EMP protection rack is installed.

As a result, in case of fire or smoke inside the EMP protection rack, it is possible to protect the server and computer equipment by early evolving the fire and to prevent the spread of the fire to the whole indoor room where the EMP protection rack is installed Requires automatic fire extinguishing function.

(Reference 1) Korean Patent Publication No. 10-2005-0082190, (June 23, 2005) (Reference 2) Korean Patent Publication No. 10-0785910, (2007.12.17.) (Reference 3) Korean Patent Registration No. 10-0990828, (Oct. 29, 2010) (Reference 4) Korean Patent Publication No. 10-1036816, (May 25, 2011) (Reference 5) Korean Patent Laid-Open Publication No. 10-2013-000918, (2013.01.24.) (Reference 6) Korean Patent Publication No. 10-1081578, (2011.11.08.) (Reference 7) Korean Patent Registration No. 10-1297895, (2013.08.22.) (Reference 8) Korean Patent Laid-Open Publication No. 10-2014-0046750, (Apr. 21, 2014) (Reference 9) Korean Patent Laid-Open Publication No. 10-2014-0-77269, (June 24, 2014) (Reference 10) Korean Patent Publication No. 10-0806066, Feb. 21, 2008. (Reference Document 11) Korean Patent Publication No. 10-0932097, December 16, 2009. (Reference 12) Korean Patent Registration No. 10-0932099, December 16, 2009. (Reference 13) Korean Patent Registration No. 10-1209706, 2012.12.11. (Reference Document 14) Utility Model Registration No. 20-0447030, Registered on Dec. 21, 2009 (Reference 15) Korean Utility Model Registration No. 20-0452293, Feb. 16, 2011. (Reference 16) Korean Patent Registration No. 10-1212982, December 18, 2012

SUMMARY OF THE INVENTION It is intended to provide an EMP protection rack capable of preventing dust from entering equipment inside the EMP protection rack, maintaining a constant temperature / humidity, fire monitoring, early evolving, and remote control, with EMP shielding being ensured.

That is, the present invention intends to provide an EMP protection rack having a constant temperature and humidity module so that the EMP protection rack can always maintain a constant temperature and humidity and can operate stably with optimum efficiency.

In particular, the constant temperature and humidity module forms a chamber in the EMP protection rack and allows the EMP protection rack to be installed and replaced in a convenient manner. Thus, the EMP protection rack is structured to have a completely closed circulation structure. In addition, So that the server and the communication device mounted inside the EMP protection rack can be operated normally even in the case of replacing the constant temperature and humidity module with a failure or the like.

In addition, the present invention aims to provide an EMP protection rack that can be used and managed stably and efficiently by providing an emergency escort device to prevent fire due to internal heat generation of the EMP protection rack.

That is, the present invention prevents the internal temperature from rising by forcibly discharging the high-temperature internal air to the outside and sucking the external air at the same time in case of emergency such as interruption of the constant temperature / To provide an emergency protection device so that the computer equipment in the EMP protection rack can be continuously operated without interruption.

The present invention also relates to an automatic fire extinguishing system using a solid aerosol (Fixed Condensed Aerosol) fire extinguishing device installed in an EMP protection rack to monitor internal fire, automatically detect fire (smoke, abnormally high temperature, etc.) And an automatic fire extinguishing system in which fire extinguishing is performed.

That is, according to the present invention, a detector and a fire extinguishing device are installed in the EMP protection rack to enable rapid early evolution in case of fire, thereby preventing the spread of fire into an indoor room equipped with an EMP protection rack, Servers, and computer equipment.

In addition, the present invention can be applied to an EMP protection rack by configuring a server installed in an EMP protection rack and a remote control device so that the status of computer equipment can be remotely controlled by a manager using various mobile devices (PC, tablet, etc.) So that it can be more stable and more efficient.

According to an aspect of the present invention,

The invention described in claim 1 is characterized in that: A rack box for mounting the computer equipment therein; A compartment formed at a lower portion of the rack and capable of separating and coupling the constant temperature and humidity module that maintains the inside of the rack at a constant temperature and humidity; An outer air circulation duct for dissipating the refrigerant condensation heat of the inner air circulation duct contributing to the constant temperature and humidity is built in as a partition wall, And a thermostatic / moisture-proof module, which is composed of a box and is slidably coupled to the lower compartment of the rack box. And a blowing chamber communicating with the outlet port of the internal air circulating duct is provided at one side of the duct to communicate with the outlet duct on the side of the rack and the discharge duct which blows the cooled / heated internal air to the inside of the rack through the discharge hole. , Said chamber being provided with: Wherein the outer air inlet port for introducing the outside air into the outside air circulation duct and the outlet port for connecting the outlet air to the discharge duct for discharging the introduced outside air to the discharge hole are communicated with each other, And an EMP shielding member for shielding the EMP shielding member.

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The EMP protection rack is structured to have a completely closed structure to reliably block the inflow of external dust and maintain a constant temperature and humidity at all times, thereby enabling stable operation with optimum efficiency.

That is, according to the present invention, since the inside of a sheltered EMP protection rack is simultaneously controlled by a refrigerant cycle device and a heating device using a compressor and a refrigerant, the temperature is always maintained at a constant temperature to stably operate at an optimum efficiency And the like.

Particularly, since the constant temperature and humidity module can be installed and exchanged as a deposit and withdrawal, the EMP protection rack can be constructed in a completely closed circulation structure. In addition, only the constant temperature and humidity module can be replaced easily, Even in the case of replacing a constant temperature and humidity module, servers and communication devices installed in the EMP protection rack provide the advantage of normal operation.

In addition, according to the present invention, when an emergency situation such as a shutdown of the temperature / humidity module is generated or an abnormally high temperature occurs, the emergency protection device operates and the computer equipment can be normally operated without interruption due to the internal heat load of the rack.

In addition, the present invention separates and supplies the EMP protection rack and the emergency protection device from the UPS power supply (uninterruptible power supply) and the general power supply, so that the emergency protection device can smoothly operate even during power failure, It can prevent and protect internal servers and computer equipment from being shut down or damaged even when the temperature and humidity module is shut down or abnormally high temperature occurs.

In addition, the present invention can be expected to provide many advantages and effects such as providing an EMP protection rack with excellent functionality and excellent safety, such as being capable of more stable and efficient operation and management, enabling remote tasks using various mobile devices have.

1 is a perspective view of an EMP protection rack according to an embodiment of the present invention, in which a constant temperature and humidity module is detached;
2 is a perspective view of the EMP protection rack according to the present invention in which the constant temperature and humidity module is coupled to the door and the door is opened.
Fig. 3 is a perspective view of the EMP protection rack of the present invention, in which the constant temperature and humidity module is coupled to the door and the door is closed.
Fig. 4 is a front view of the EMP protection rack according to the present invention in which the constant temperature and humidity module is coupled to the door and the door is opened. Fig.
FIG. 5 is a partially exploded perspective view of the essential part of the constant temperature and humidity module of the present invention. FIG.
6 is a front view of an operating state for explaining an operating state of the present invention.
FIG. 7 is an enlarged cross-sectional view showing a configuration of an internal air circulation duct of the present invention. FIG.
8 is a cross-sectional view showing the configuration of an external air circulation duct of the present invention.
FIG. 9 is a rear perspective view showing a connection structure of a power line and a communication line in the present invention. FIG.
10 is a perspective view showing the operating state of the emergency protection device of the present invention.
11 is a sectional view showing an operating state of the emergency protection device according to the present invention.
12 is a cross-sectional view of the main part showing the operating state of the exhaust damper,
(A) is a closed state, and (b) is an open state.
13 is a cross-sectional view of the main portion showing the operation state of the intake damper,
(A) is a closed state, and (b) is an open state.
FIG. 14 is a front elevational view of a door open state of an EMP protection rack to which an automatic fire extinguishing apparatus is applied according to the present invention. FIG.
FIG. 15 is an enlarged view of a portion of FIG. 14; FIG.
16 is an enlarged cross-sectional view showing a configuration of an automatic fire extinguishing apparatus according to the present invention.
17 is an exploded perspective view showing a configuration of an automatic fire extinguishing apparatus according to the present invention.
18 is a perspective view showing a configuration example of a UPS power supply according to the present invention.

SUMMARY OF THE INVENTION It is composed of a rack box which is constructed to shield the induction field of lightning, noise and electromagnetic waves generated from the outside by a metallic structure and which houses a server and a computer, and a door which is openably and closably connected to the front of the rack. It is characterized by a constant temperature and humidity module that keeps the inside of the rack of the EMP protection rack constantly at constant temperature and humidity in the rack.

Particularly, the present invention is characterized in that the above-mentioned constant temperature and humidity module is formed in a lower portion of the rack and is detachable to and from the chamber so that the temperature and humidity module is mounted inside the enclosed rack, In case of maintenance and management of the thermostat and humidity module, it is possible to operate servers and computer equipment in the rack in a normal manner.

The constant temperature and humidity module is provided with a refrigerant cycle device using a compressor and a refrigerant, a heating device using a heater, and the like. The cooling and heating control simultaneously controls the inside of the EMP protection rack at a constant constant temperature. It consists of an internal air circulation duct for circulation of the rack air and an external air circulation duct for the heat dissipation of condensation heat.

The internal air circulating duct is constituted by installing an evaporating fan (suction fan), an evaporator (evaporating coil) and a heater for sucking the inside air of the rack while circulating the inside of the rack while circulating the inside of the rack, A condenser (condensing coil) and a condensing fan (blowing fan) for condensing the high-temperature refrigerant generated in the evaporator of the air circulation duct, and a compressor for circulating and supplying the refrigerant of the evaporator and the condenser are installed to radiate the condensation of the refrigerant .

In addition, the above-mentioned constant temperature and humidity module is constructed by dividing an internal air circulation duct and an external air circulation duct as partition walls, and by appropriately combining cooling and heating by PID control (Proportional-Integral-Derivative Control) by cooling and heating in an internal air circulation duct And the external air circulation duct is constituted by an operation structure for dissipating the heat of condensation of the refrigerant contributing to the constant temperature and humidity of the internal air circulation duct separately from the internal air circulation duct.

The present invention also provides It is characterized by an emergency protection device in the EMP protection rack.

That is, the present invention provides an emergency damper, which is provided with an exhaust damper for discharging the air inside the rack and an intake damper for introducing the outside air into the rack, in case of an emergency such as interruption of the operation of the constant temperature / .

The exhaust damper is provided at an upper portion of the rack to facilitate the discharge of high-temperature air inside the rack, and an exhaust fan is installed to forcibly discharge the internal air. The inlet damper is formed at the lower portion of the rack to forcefully discharge the inside air, Of the fresh air of the rack to the inside of the rack.

The present invention also provides It is characterized by an automatic fire extinguishing system inside the EMP protection rack. When a fire occurs inside the rack box, the automatic fire extinguishing system installed in the rack box detects it and automatically operates the fire extinguisher. To protect the servers and computer equipment in the rack, and to prevent the spread of fire into the room.

That is, the present invention provides an automatic fire extinguishing system including a fire detector such as a server or a computer in the rack, and a fire extinguisher that extinguishes fire by spraying fire extinguishing agent in conjunction with the fire detector.

The detector detects smoke or abnormal high temperature generated by a fire, and the fire extinguisher is a solid aerosol fire extinguishing device which generates a fire extinguishing gas while being ignited and burned by the combustion means with the solid extinguishing agent and coolant contained in the housing tube.

The fire extinguisher has an enclosure for installing a fire extinguisher on the upper part of the rack, a housing tube of the fire extinguisher is fixed to the enclosure, and the eastern part of the fire extinguisher is exposed to the top surface of the rack. So that the fire extinguishing agent is discharged into the rack box.

In addition, the present invention is characterized in that a state of a server, a computer equipment, and the like mounted inside the EMP protection rack can be confirmed and managed by various mobile devices.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not to be construed in a limiting sense by the scope of the invention as defined in the appended claims. It will be apparent to those skilled in the art that variations and modifications are possible.

FIG. 1 is a perspective view of the EMP protection rack according to the embodiment of the present invention in which the temperature and humidity module is detached. FIG. 2 is a perspective view of the EMP protection rack of the present invention, FIG. 3 is a perspective view of the EMP protection rack according to the present invention in a state in which the door is closed and a constant temperature and humidity module is connected to the rack. FIG. 4 is a front view of the EMP protection rack, FIG. 5 is a partially exploded perspective view of the main part of the constant temperature and humidity module of the present invention, FIG. 6 is a front view of the operating state for explaining the operation state of the present invention, and FIG. 7 is an enlarged cross- FIG. 8 is a cross-sectional view showing a configuration of an external air circulation duct according to the present invention. FIG.

The EMP protection rack (R) comprises: And a door 10 which is openably and closably connected to the front surface of the rack box 1. The rack box 1 is provided with a server 1, a computer, a communication device, etc. (hereinafter collectively referred to as computer equipment) The construction of such an EMP protection rack R is known.

In the present invention, a chamber 13 is formed below the rack 1 of the EMP protection rack R, and the constant temperature and humidity module 3 is detachably mounted thereon.

The constant temperature and humidity module (3) is detachably attached to the chamber (13) below the rack box (1); A cooling device using a coolant and a heating device using a heater 45 are installed together so that the inside of the rack 1 can be maintained at a constant temperature and humidity by simultaneous control by cooling control and heating control.

The constant temperature and humidity module (3) comprises: The housing 32 is divided into an internal air circulation duct 4 and an external air circulation duct 8 as partition walls 31 inside the housing 32. The housing 32 in which the housings 32 are housed is housed in a box BOX) so that they can be slidably received in the chamber 13 under the rack box 1, separated and combined.

To this end, the constant temperature and humidity module (3) comprises: It is a matter of course that the refrigerator 1 should have a standard size (width × length × height) conforming to the lower compartment 13 of the rack 1, (Not shown) may be added in order to facilitate the receipt and delivery of money to the user.

A door 10 installed on the front surface of the rack box 1 is opened and closed by a hinge so that the rack box 1 including the chamber 13 closes the door. It is natural that it can be carried out only in front or rear.

An internal air circulation duct 4 for circulating the internal air of the constant temperature and humidity module 3 mounted on the lower housing 13 of the rack 1; A suction fan 41 for sucking the inside air from the inside of the rack box 1 and blowing air to the evaporator 42, an evaporator 42 for cooling the inside air sucked through the suction fan 41, And a heater 45 for heating the inside air sucked through the heater.

The rack box 1 is provided with an air blowing chamber 17 for communicating with the internal air circulating duct 4 to circulate and supply the internal air sucked from the rack 1 again into the rack 1 ), A discharge duct (7), and the like.

Hereinafter, the structure of the internal air circulation duct 4 of the temperature and humidity module 3 will be described in detail.

First, in the rack box 1, discharge holes 11 and 11 'for circulating the internal air through the internal air circulating duct 4 are formed at one side for maintaining the constant temperature, and the discharge holes 11 and 11' (12) for discharging air to the internal air circulation duct (4).

The lower end of the discharge duct 12 coupled to one side discharge hole 11, 11 'of the rack box 1 is formed to communicate with the lower chamber 13 of the rack 1.

The lower end of the discharge duct 12 is connected to the suction port 41 of the internal air circulation duct 4 of the constant temperature and humidity module 3 through the chamber 13.

That is, the lower end of the exhaust duct 12 is formed to communicate with the lower housing 13 of the rack 1, and the constant temperature and humidity module 3 coupled to the housing 13 is connected to the inlet of the internal air circulating duct 4, The discharge duct 13 of the one discharge hole 11 and the discharge duct 13 of the one discharge hole 11 are connected to the inside of the constant temperature and humidity module 3 through the chamber 13, (41) of the air circulation duct (4).

The inside of the intake port 41 of the internal air circulation duct 4 is connected to the inside of the rack 1 through the exhaust holes 11 and 11 'of the rack 1 communicated with the chamber 13 and the exhaust duct 12, A suction fan 42 for sucking air and an evaporator 43 for cooling the inside air blown through the suction fan 42 are installed.

A discharge port 44 for supplying the internal air cooled by the evaporator 43 to the inside of the rack 1 is formed on the side opposite to the suction port 41 provided with the suction fan 42 and the evaporator 43.

The outlet 44 is connected to the blowing chamber 17 provided between the rack 1 and the chamber 13 to communicate with each other.

The blowing chamber (17) comprises: A partition wall is formed between the chamber 13 of the rack box 1 and the constant temperature and humidity module 3 in which the internal air circulation duct 4 is built and the feed passage 18 is formed on one side, And is coupled to the installed discharge duct (7).

The blowing chamber (17) comprises: The rack 1 and the chamber 13 are formed so as to be isolated from each other and one outlet port 44 of the internal air circulation duct 4 of the constant temperature and humidity module 3 coupled to the chamber 13 is connected to the discharge duct 7 side The inside air of the rack 1 is sucked through the discharge holes 11 and 11 'and the discharge duct 12 by being communicated with the delivery path 18 and then cooled by the evaporator 43 or heated by the heater 45 The air is blown through the discharge holes 72 and 72 of the discharge duct 7 in the rack 1 through the inlet 71 of the discharge duct 7 communicated with the discharge passage 18 of the rear blowing chamber 17, Circulation.

The heating control by the heater 45 enables simultaneous control of cooling / heating together with cooling control by the evaporator 43.

Referring again to the discharge duct 7 coupled to the upper portion of the discharge passage 18 of the blowing chamber 17, The discharge duct 7 is formed with discharging holes 72 and 72 'at one side of the inside of the rack box 1 (opposite sides of the discharging holes 11 and 11') and the lower inlet 71 is connected to the blowing chamber 17, To be connected to the upper portion of the delivery path (18).

The discharging holes 72 and 72 'of the discharging duct 7 can be blown and circulated evenly inside the rack 1 as shown in FIG. To be uniformly arranged,

Also, the discharge holes 11 and 11 'provided on the opposite sides of the discharge duct 7 are also racked up and down at regular intervals so that the inside air of the rack 1 can be sucked and circulated evenly through the internal air circulating duct 4 (On the opposite side of the discharge duct 7) of the discharge duct 1, as shown in Fig.

The rack 1 and the internal air are racked 1 by the suction force of the suction fan 43 installed in the internal air circulation duct 4 of the constant temperature and humidity module 3 mounted on the lower housing 13, , 11 ', the exhaust duct 12 and the suction port 41, cooled / heated so as to maintain a constant temperature / humidity by the evaporator 43 and the heater 45, And is circulated into the rack 1 through the chamber 17 and the discharge duct 7.

The heater 45 is installed under the outlet 44 so that the internal air sucked by the suction fan 42 is heated before being blown through the blowing chamber 17 to be supplied into the inside of the rack 1, 1) Ensure that the inside temperature is constantly maintained at all times.

On the other hand, in the constant temperature and humidity module 3, an external air circulation duct 8 is provided on the opposite side of the internal air circulation tube 4 and the partition 31.

The external air circulation duct 8 is connected to the condenser 82 and the cooling fan 83 to heat the heat of the internal air recovered in the evaporator 43 of the internal air circulation tube 4, ).

Hereinafter, the external air circulation duct 8 will be described in detail.

The external air circulation duct (8) comprises: A condenser 82 and a cooling fan 83 for supplying the refrigerant to the evaporator 43 and circulating the refrigerant to the evaporator 43. The internal air circulation tube 4 and the partition 31 are installed.

The constant temperature and humidity module (3) in which the external air circulation duct (8) is installed is provided with: An inlet 84 for introducing outside air from the outside is formed on one side of the housing 32 and a cooling fan 83 is provided on the side opposite to the cooling fan 83 on the side where the cooling fan 83 is installed, And an outlet 85 for discharging air is formed.

The outside air inlet 14 is formed in the chamber 13 of the rack box 1 so as to communicate with the inlet 84 at one side of the constant temperature and humidity module 3 mounted in the chamber 13, 3 to the inlet 84 formed in the external air circulation duct 8.

A discharge duct 15 communicating with the discharge port 85 of the constant temperature and humidity module 3 (formed at the upper portion of the cover 33 of the housing 32) is formed at one side of the chamber 13 of the rack box 1, The external air introduced through the inlet 14 and the inlet 84 is exhausted through the external air circulation duct 8 via the exhaust port 85 and the exhaust duct 15.

The external air circulation duct 8 includes: Is separately operated from the internal air circulation duct (4) provided with the partition (31) interposed therebetween so that the condensation heat of the internal air condensed by the evaporator (43) radiates heat while circulating external air.

An EMP shielding member (not shown) is connected to the outer air inflow port 14 at one side of the cabinet 3 of the rack box 1 and the upper vent hole 16 of the exhaust duct 15 by a honeycomb structure or a mesh structure, To block EMP penetration into the rack (1).

The EMP shielding member, which can be embodied by the honeycomb or mesh structure, is provided with a sealing means such as a conductive fiber or a fiber gasket for sealing the EMP shielding member to the outside air inlet 14 at one side of the chamber 3, (16), or the like, so as to shield the EMP.

The EMP shielding member applied to the upper air outlet 16 of the discharge duct 15 and the outer air inlet 14 at one side of the chamber 3 can be implemented by various EMP shielding means and methods known in the above- Of course.

The present invention is characterized in that the air inside the rack 1 of the EMP shielding rack R in which the EMP shielding is made and the inside is sealed is cooled and cooled by the evaporator 43 and the heater 45 of the internal air circulation duct 4, The heated internal air is blown into the discharge duct 7 through the blowing chamber 17 and is cooled and heated in the process of circulating in the rack 1 through the discharge holes 72 and 72 ' PID control (Proportional-Integral-Derivative Control) by the appropriate combination of cooling and heating to maintain constant temperature without any variation.

Particularly, the present invention is characterized in that the constant temperature and humidity module (3), in which the rack (1) performs a constant temperature and humidity function, can be detached from the rack (1) In the case of a failure of the constant temperature and humidity module 3, the door can be easily opened by opening the door 10. (1) While the computer equipment is normally operated, Only the module 3 can be easily separated and can be easily and efficiently repaired, maintained, and managed.

On the other hand, the power line and the communication line (2, 2 ') which are wired into the rack box 1 from the outside; As shown in FIG. 9, the EMP filters 21 and 21 'are attached to the inside of the rack 1 through the same, thereby protecting the computer equipment installed in the rack 1 from the EMP. The communication lines 2 and 2 'can be implemented by attaching various EMP filters 21 and 21' freely according to the position and the quantity of the communication lines 2 and 2 '. The configuration and the like of the EMP filters 21 and 21 'are known.

Hereinafter, an emergency protection device provided in the present invention will be described.

10 to 13 are views showing an emergency protection device according to the present invention. FIG. 10 is a perspective view showing an operation state of the emergency protection device according to the present invention, FIG. 11 is a sectional view showing an operation state of the emergency protection device according to the present invention, Fig. 12 is a sectional view of the main part showing the action state of the exhaust damper, Fig. 13 is a sectional view of the main part showing the action state of the intake damper, Fig. Front view.

To said rack (1); When the constant temperature and humidity module 3 is not operated due to a power failure or the like due to the provision of the exhaust damper 5 and the intake damper 6 and an abnormality higher than the set temperature occurs in the rack 1, the exhaust damper 5 is opened (1) Forced discharge of hot air inside the rack (1) and external air to the inside of the rack (1) through the intake damper (6). (1) A protection device is constituted.

The exhaust damper (5) comprises: The intake damper 6 is provided at an upper portion of the rack 1 so that the hot air inside the rack 1 can be easily discharged to the outside. The intake damper 6 introduces outside air into the rack 1, It is preferable to install it in the lower part of the rack box 1 so that ventilation and cooling of the rack box 1 can be performed.

The exhaust damper 5 is provided with an exhaust duct 51 on an upper portion of the rack box 1 and an exhaust cover 52 is installed on the exhaust duct 51 to open and close.

The exhaust cover (52) comprises: A bracket 55 is coupled to the rack box 1 with the exhaust duct 51 formed therein and an exhaust cover 52 is provided on the bracket 55 to be openable and closable by a damper motor 53.

That is, the bracket 55 is coupled to the exhaust duct 51 of the rack box 1, and the damper motor 53 is installed on the bracket 55 to connect the exhaust cover 52 So that the exhaust duct 51 can be opened and closed by the exhaust cover 52 provided on the rotary shaft 54 of the damper motor 53. [

In the exhaust duct 51 provided with the exhaust cover 52 as described above, The exhaust duct 51 is opened by the exhaust cover 52 when the operation of the constant temperature and humidity module 3 is stopped due to a power failure or the like and an abnormally high temperature is generated inside the rack 1, At the same time, the exhaust fan 56 is operated to forcibly exhaust the hot air in the rack 1.

The exhaust fan 56 is installed inside the exhaust duct 51 so that the air inside the rack 1 can be forcibly discharged through the exhaust duct 51.

An intake damper (6) for introducing outside air into the rack (1) is provided under the rack box (1).

The intake damper (6) comprises: It is preferable that the external air is introduced from the lower part of the rack box 1 and installed under the rack box 1 so that the external air can be discharged and vented through the upper exhaust damper 5.

 In the present invention, as a most preferred embodiment, the door 10 is provided on the door 10 opened and closed on the front surface of the rack 1. However, the rack 1 can be directly installed on the rack 1 according to the shape, There is also.

The intake damper 6 is installed in the intake duct 61 so as to open and close the intake cover 62 so that outside air can be introduced into the rack 1 when the intake damper 6 is opened.

The intake cover (62) comprises: An installation bracket 65 is provided on the intake duct 61 and the intake cover 62 is coupled to the installation bracket 65 by means of the rotation shaft 64 of the damper motor 63 so as to be openable and closable. That is, the intake cover 62 is installed on the rotary shaft 64 of the damper motor 63 and rotates the rotary shaft 64 by the damper motor 63 to open and close the intake duct 61 with the intake cover 62 .

The intake duct 61 of the intake damper 6, in which the intake cover 62 is opened and closed, Like the honeycomb structure or the mesh structure in the same manner as the case of the EMP shielding member provided on the outer air inflow inlet 14 on one side of the chamber 3 of the rack box 1 and on the upper vent hole 16 of the discharge duct 15, (Not shown) are coupled to block the penetration of the EMP into the rack 1 through the intake damper 6.

The emergency protection device of the above-mentioned configuration comprises: The exhaust damper 5 having received the detection signal is opened when the constant temperature and humidity module 3 that keeps the rack box 1 at constant temperature and humidity is in an emergency such as interruption of operation due to power failure or other causes, At the same time, the exhaust fan 56 is operated to exhaust the hot air inside the rack 1 through the exhaust damper 5 to the outside.

Simultaneously with the opening of the exhaust damper 5, fresh air is introduced into the rack 1 through the intake damper 6 which is opened by opening the intake damper 6, thereby preventing the internal temperature of the rack 1 from rising And the computer equipment is operated in an emergency so as to be continuously operated normally. This will be described in detail below.

The operation of the constant temperature / constant humidity module 3 is stopped due to a power failure or other cause in the EMP protection rack R in normal operation in the closed state in which the exhaust damper 5 and the intake damper 6 of the rack box 1 are both closed A signal sensed by the abnormally high temperature is transmitted to the exhaust damper 5, the exhaust fan 56 and the intake damper 6 so that they are opened simultaneously.

The sensing means and method, the signal transmitting means, and the method for detecting the disconnection of the constant temperature / constant humidity module 3 due to the power failure or the like, and the like are general technical matters, and therefore, detailed description thereof will be omitted.

The exhaust damper 5 having received the abnormally high temperature detection signal operates the exhaust cover 52 coupled to the rotary shaft 54 by operating the damper motor 53 to open the exhaust duct 51, The exhaust fan 56 provided in the exhaust duct 51 is driven to discharge the hot air inside the rack 1 through the exhaust duct 51 to the outside.

At the same time, the intake damper 6 provided on the door 10 is opened and the outside air flows into the rack 1.

The intake duct 61 of the intake damper 6 having received the emergency signal opens the intake duct 62 by opening the intake cover 62 provided on the rotary shaft 64 by driving the damper motor 63 to open the exhaust duct 71, 1) External air enters into the inside.

As described above, the external air introduced into the rack box 1 is exhausted through the exhaust damper 5 while being sucked together with the internal hot air through the exhaust damper 5, and the external air is lashed through the intake damper 6 (1) Lack of internal temperature (1) Lack of internal temperature (1) Lack of internal air through the ventilation of external air (1) Lack of temperature rise (1) So that it can be stably operated normally.

Hereinafter, the automatic fire extinguishing system 9 of the present invention will be described.

14 to 17 show an example of the automatic fire extinguishing system of the present invention. Fig. 14 is a front view of the door open state of the EMP protection rack to which the automatic fire extinguishing apparatus of the present invention is applied, Fig. 15 is a front elevational view FIG. 16 is an enlarged cross-sectional view showing a configuration of an automatic fire extinguishing device according to the present invention, and FIG. 17 is a perspective view showing a configuration of an automatic fire extinguishing device according to the present invention.

The automatic fire extinguishing system (9) of the present invention comprises: Rack of EMP protection rack (R) (1) Detect and automatically fire fire in case of fire inside. (1) Rack out by letting fire evolve early (1) Protect my computer equipment and prevent fire spread The automatic fire extinguishing device 9 is constructed.

The automatic fire extinguishing system (9) comprises: A detector 91 for detecting a fire, and a fire extinguisher 92 for extinguishing the fire by spraying the fire extinguishing agent.

The detector 91 and the fire extinguisher 92 constituting the automatic fire extinguishing device 9 include: It is possible to effectively detect fire signs such as smoke in the rack (1) and abnormal temperatures, and to install the fire extinguishing agent on the rack (1) so that the spraying of the fire extinguishing agent can be evenly performed throughout the inside of the rack (1).

The detector 91 comprises: A sensor for detecting heat or smoke, and a controller for transmitting a signal of the detection sensor to a fire extinguisher, and it can be variously implemented as a thermal sensor wire type, a fusible metal type, a self-generating type, In the present invention, it is most preferable to carry out the self-power generation type advantageous for the operation of the EMP protection rack (R) and the operation of the automatic fire extinguisher (9).

The fire extinguisher (92) comprises: When a fire signal is transmitted from the detector 91 to the detector 91, the coolant and the solid extinguishing agent in the housing tube 56 are activated, the extinguishing agent is vaporized to a high temperature and a high pressure and is discharged through the extinguisher opening 52 Digestion is achieved.

The automatic fire extinguishing system 9 composed of the detector 91 and the fire extinguisher 92 is a solid condensed aerosol extinguishing system and its construction and operation are already known.

[Fixed Condensed Aerosol Fire Extinguishing System] Unlike fire extinguishing systems such as halogen / CO2, the above-mentioned solid aerosol fire extinguishing system is harmless to the human body and is stored in a solid state, (Refer to References 10 to 17).

The automatic fire extinguishing system 9 includes a detector 91 and a fire extinguisher 92 interlocked with the detector 91 and operated from a fire detection signal. The automatic fire extinguishing system 9 is installed above the rack 1, And an outer housing 95 for installing a fire extinguisher 92 on the outside so that the housing tube 93 of the fire extinguisher 92 is fixed to the housing 95 with the bracket 97 and the housing tube 95 The fire extinguisher 92 with the fire extinguisher 93 fixed thereon is installed inside the upper part of the rack 1 to fire the fire extinguisher 94 at the lower part where the fire extinguishing agent is sprayed.

That is, the digester 94 of the fire extinguisher 92 is exposed from the ceiling surface 11 of the rack 1 to the rack 1 and the fire extinguishing agent is sprayed from the top to the inside of the rack 1 to evolve and extinguish the fire Respectively.

A cover 96 is attached to the upper part of the enclosure 95 on which the fire extinguisher 92 is mounted so that the fire extinguisher 92 is installed in the fire extinguisher 2 by opening and closing the cover 7, So that it can be easily checked and managed from the outside.

In the present invention having the above-described configuration, the detector 91 senses smoke in the rack box 1 or an abnormally high temperature, and the fire extinguisher is immediately extinguished by the fire extinguisher 92, And can quickly evolve.

Thus, the automatic fire extinguishing system includes: Unlike conventional CO2 and halogen fire extinguishing equipment, it is possible to safely protect the computerized equipment (S) installed in the rack box (1) by early evolution of fire, and as a solid fire extinguishing agent, a solid aerosol fire extinguisher (S) can be continuously operated during fire extinguishing operation and the fire prevention of the EMP protection rack (R) prevents fire spread to the server room where the EMP protection rack (R) is installed. can do.

18, the constant temperature / constant humidity module 3 is connected to the general power source 2A (commercial power source), and the exhaust damper 5 and the exhaust fan 56 of the rack box 1 and the intake damper 6) can be connected to the UPS power supply (2B) together with a controller with little power consumption, so that the emergency protection device can be operated normally during an emergency such as a power failure.

That is, in an emergency such as interruption of operation due to power failure or other causes, abnormal high temperature occurs, the exhaust damper 5 connected to the UPS power supply 2B, the exhaust fan 56 and the intake damper 6 are operated in an emergency, The protection rack R can be normally operated to protect the computer equipment mounted in the rack box 1, or the like.

Meanwhile, the present invention can be implemented by constructing a remote control unit (RCU) to remotely manage and control the state of the computer equipment installed in the EMP protection rack (R).

That is, the state of the computer equipment mounted in the rack 1 of the EMP protection rack R and the EMP protection rack R (the internal temperature of the rack 1, abnormal heat detection, fire detection, And so on) to collect SMS and send it through SMS to various mobile devices (smartphone, tablet, PC, etc.) so that the administrator can check it anytime and anywhere regardless of place and time. Configure the remote control unit.

Said remote control device comprising: The status of the EMP protection rack R and the computing equipment in the rack 1 of the EMP protection rack R can be collected and stored at all times and the collected information can be provided to the administrator It is possible to confirm the state of the computer equipment in the rack 1 of the EMP protection rack R and the EMP protection rack R by using various mobile devices or the like.

For example, when a problem occurs in the EMP protection rack (R) and in the computer equipment in the rack (1) of the EMP protection rack (R), the alarm is reported to the registered administrator through SMS transmission system, Allows control and monitoring of EMP protection racks and computer equipment without being constrained to time and place.

In addition, measures are taken for normal operation even after the remote controller notifies the administrator of the abnormality in the EMP protection rack (R) and the computer equipment in the rack (1) of the EMP protection rack (R) If not, you can operate the integrated control center so that you can contact the manager directly.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other objects, features and advantages of the present invention will become more apparent from the following description taken in conjunction with the accompanying drawings, in which: FIG.
1: Racking 10: Door
11, 11 ': Exhaust hole 12: Exhaust duct
13: cabinet 14: outside air inlet
15: discharge duct 16: discharge hole
17: air blowing chamber 18:
2,2 ': Power line and communication line 21,21': EMP filter
2A: General Power 2B: UPS Power (Uninterruptible Power Supply)
3: Constant temperature and humidity module 31:
32: housing 33: cover
4: internal air circulation duct 41: inlet
42: Suction fan 43: Evaporator
44: outlet 45: heater
7: Discharge duct 72, 72 ': Discharge hole
8: External air circulation duct 81: Compressor
82: condenser 83: cooling fan
84: Inlet port 85: Outlet port
5: exhaust damper 51: exhaust duct
52: exhaust cover 53: damper motor
54: rotating shaft 55: bracket
56: Exhaust fan
6: intake damper 61: intake duct
62: intake cover 63: damper motor
64: rotating shaft 65: bracket
9: Automatic fire extinguisher 91: Detector
92: fire extinguisher 93: housing tube
94: Fire extinguisher Eastern 95: Enclosure
96: Cover 97: Bracket
It is to be understood that both the foregoing description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed and the appended claims. The meaning and concept of the term used should not be interpreted in an unclear way by limiting it to meaning.

Claims (8)

A rack (1) for mounting the computer equipment therein; A chamber 13 formed at a lower portion of the rack box 1 and capable of separating and coupling the constant temperature and humidity module 3 to maintain the inside of the rack box 1 at a constant temperature and humidity; An external air circulation duct 8 for dissipating the refrigerant condensation heat of the internal air circulation duct 4 contributing to the constant temperature and humidity and the internal air circulation duct 4 for maintaining the inside air of the rack box 1 by cooling / And a constant temperature and humidity module (3) composed of a box with a cover (33) coupled to the upper part of the partition wall (31) and slidably coupled to the lower chamber (13) of the rack (1) In the protective rack,
The chamber (13) comprises: And a blowing chamber 17 communicating with the outlet port 44 of the internal air circulation duct 4 is provided at one side of the rack chamber 1 and the suction port 41 of the internal air circulation duct 4 is communicated with the one outlet duct 12, And communicates the cooled / heated internal air to the discharge duct 7 which blows air into the rack 1 through the discharge holes 72 and 72 '
In the chamber 13, An outside air inlet 14 for introducing outside air into the outside air circulating duct 8 and an outlet 85 connected to a discharging duct 15 for discharging the introduced outside air to the outlet hole 16 are formed to communicate with each other In addition,
Wherein an EMP shielding member for blocking EMP penetration is coupled to the air inlet (14) of the chamber (13) and the discharge hole (16) of the discharge duct (15). delete delete delete delete delete delete delete

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