WO2017157204A1 - System for defending against electromagnetic pulse attack for container-type data center - Google Patents

Abstract

A system for defending against an electromagnetic pulse attack for a container-type data center consists of an electromagnetic pulse defense system, a container body structure, a shutter, an electrical system, a communication network, a controller, a bracket, and a vertical cooling system. In an inner-layer shielding body, a signal-wire and control-circuit protector is serially connected to a signal wire. A first power supply surge protection device (SPD) is connected to a power supply wire in parallel, a fourth power supply surge protection device (SPD) is connected to the inner-layer shielding body, and a second power supply surge protection device (SPD) is connected to a first cooling liquid/water duct, and a third power supply surge protection device (SPD) is connected to a second cooling liquid/water duct, so that with the aid of the inner-layer shielding body, the connections form a protective layer that cannot be broken through by an outside electromagnetic field, and high currents transiently sensed on the signal wire, the power supply wire, the inner-layer shielding body, the first cooling liquid/water duct and the second cooling liquid/water duct are offloaded, thereby protecting the data center in the inner-layer shielding body.

Description

Defensive electromagnetic pulse attack system for containerized data center Technical field

The invention relates to an inner layer shielded body signal line, a control line protector and a signal line connection and a plurality of power surge protectors SPD and a power line, an inner layer shield, first and second coolants/water conduits respectively A defensive electromagnetic pulse attack system connected to a containerized data center.

Background technique

1. High-energy electromagnetic pulse weapon damage to computer system

The ability of large-scale integrated circuits to resist high-energy electromagnetic pulse weapons is very weak. When an electromagnetic bomb explodes, the electromagnetic field generated by a powerful electromagnetic pulse is coupled into the computer circuit to induce a strong current, causing the digital logic circuit to instantaneously recover or flip. Permanent flipping reduces the performance of electronic components, making computer systems unable to work properly or even burning electronic components. It may also trigger the internal circuit of the system to cause disorder of working mode. With the development of ultra-large-scale solid-state integration technology, the number of components and circuits housed on the silicon wafer has been rapidly increasing, so that the current and the normal operation of the electronic device Voltage levels and the power that can cause damage are slowly decreasing, making computer systems extremely vulnerable to high-energy electromagnetic weapons.

2. Three aspects of electromagnetic pulse protection

2.1 Shielding: Shielding is the use of shielding to block or reduce the transmission of electromagnetic energy, an important means of achieving electromagnetic protection. This shielding body does not allow electromagnetic fields to reach the protected equipment.

2.2 Grounding: Grounding treatment is to connect the electronic equipment to the earth through appropriate methods and ways to improve the stability of the operation of the electronic equipment circuit system, effectively suppress the influence of the external electromagnetic field, and avoid the discharge caused by excessive accumulation of electric charge in the casing. Interference and damage.

2.3 Filter: The filter can be composed of a passive or active device such as a resistor, an inductor or a capacitor to form a selective network to prevent the passage of the remaining components outside the useful band, to complete the filtering, or to be a ferrite. Loss material composition, which absorbs unwanted frequency components and achieves filtering.

3. The most advanced power surge protector (SPD) in the world; introduction of signal line and control line protector technology:

3.1 Multi-level protection mechanism, residual voltage up to 0V. The surge voltage after the diversion is generally between 2.5KV and 15KV. The SPD products equipped should be subjected to multi-stage protection to achieve extremely low residual voltage, and the special industry can reach 0 volts.

3.2 Response speed is less than 1 nanosecond, effectively protecting secondary lightning, inductive lightning and electrical internal inrush transient voltage suppressor (TVS for short). The TVS diode response time is less than 1 nanosecond.

3.3 The casing is made of NEMA 4, waterproof, fireproof, explosion-proof and anti-static.

3.4 Patented sine wave ORN tracking technology to accurately eliminate surge and harmonic functions. The traditional product adopts the traditional upper and lower clamp type threshold filtering, and the pressure sensitive characteristic is that the ground is turned on when the voltage reaches the threshold value, thereby achieving the purpose of discharging the current.

3.5 Unique chemical packaging patent technology to ensure long-lasting reliability of the device.

3.6 True 10-mode (full-mode) protection that blocks all possible channels of surge. The device requires filtering protection between the line and the line. S product full-mode protection, blocking all possible channels of lines and lines, lines and ground, thus perfect protection of the equipment

3.7 Hybrid diversification module, thermal and electric double fuse fuse capacitor design.

3.8 The only surge protection product that can be ungrounded. (Reference: American company "Series Product Manual")

4. The containerized data center is a low-cost, highly integrated, energy-efficient, flexible, and rapidly deployed data center solution that is gradually being adopted by major vendors. The design concept of containerized data center is: easy to carry, low cost (no need to spend a lot of money in land approval and plant construction), fast construction, no need to be restricted by the site, using abandoned sites, you can quickly build a short-term data center.

The Chinese invention patent (application number: 201210271844.0) discloses a data center comprising a plurality of brackets, each bracket including a device receiving portion, the device receiving portion being positioned at an open bottom openly communicating with the lower plenum and Between the open top that is open to communication with the upper plenum.

The inadequacy of the above data center is that after the electromagnetic pulse generated by the explosion of the electromagnetic pulse weapon penetrates the outer casing, the electronic components of the data center and the electronic components of the integrated circuit with the chip are quickly destroyed, and the entire data center will be paralyzed.

Summary of the invention

The existing containerized data center cannot prevent the electric field and magnetic field generated by strong electromagnetic pulses from entering the shield body or directly penetrating the container along the power line cable, signal line cable or grounding wire, destroying the data center in the container. insufficient. The invention relates to a signal line, a control line protector and a signal line connected in series; the first power surge protector SPD is connected in parallel with the power line; the fourth power surge protector SPD is connected to the inner shield, The second power surge protector SPD is connected to the first coolant/water conduit; the third power surge protector SPD is connected to the second coolant/water conduit, and is disposed on the signal line, the power line, and the inner shield. The large current unloading instantaneously on the upper, first coolant/water conduit and the second coolant/water conduit forms a closed protective layer that the external electromagnetic field cannot penetrate, and the inner shield is protected by the inner shield. The data center's containerized data center's defensive electromagnetic pulse attack system consists of the following systems and devices: defense against electromagnetic pulse attack systems, cabinet structures, blinds, electrical systems, communication networks, controllers, bays, and verticals. cooling system.

Providing an inner layer shielding body inside the box body, a first heat dissipation plate and a second heat dissipation plate are disposed on the inner layer shielding body, a first ventilation chamber is left outside the first heat dissipation plate; and a second ventilation chamber is left in the second heat dissipation plate; A data center is provided in the inner shield. The inner shield is centered on the first venting chamber and the second venting chamber is located on both sides of the cabinet to form a complete modular container data center. The first heat sink and the second heat sink can effectively dissipate heat and conduct heat through the first venting chamber and the second venting chamber. The first door and the second door are provided in the second ventilation protection room, and the first door and the second door are staggered and installed in a straight line.

The first heat dissipation plate is composed of a plurality of first ventilation pipes installed thereon for guiding the hot air of the data center to the first ventilation chamber; the spiral conduit is installed at both ends of the first ventilation pipe bent at 90° at both ends The first contact opening of the spiral conduit is connected to the seventh contact opening of the first ventilation tube; the first contact opening of the spiral conduit is connected to the eighth contact opening. The second heat dissipation plate is composed of a plurality of second ventilation pipes installed thereon for guiding the hot air of the data center to the second ventilation chamber; the spiral conduit 535 is installed with two of the second ventilation pipes bent at 90° at both ends a first contact opening of the spiral conduit is connected to the ninth contact opening of the second ventilation tube; The first contact opening of the conduit is coupled to the tenth contact opening of the second vent tube.

A rubber sleeve made of a conductive magnetically conductive material, the front part of the rubber sleeve is larger than the rear part of the rubber sleeve. The inner shield is fixed to the casing by a plurality of inner welds and outer welds or by inner and outer screws, and the casing refers to an inner shield. The contact part is sleeved with a rubber sleeve made of a conductive magnetic conductive material, the front part of the rubber sleeve is larger than the rear part of the rubber sleeve, and the rear part of the first door and the second door has a convex part for preventing electromagnetic field from entering, in the first After the door leaf of the door and the second door is closed with the door frame, the rubber sleeve is in close contact with the contact portion of the door frame to form a conductive magnetic shielding body. The connecting port is composed of a connecting column and a connecting port, and the rule is distributed around the door frame. The two adjacent connecting ports are misaligned, respectively parallel to and perpendicular to the door frame, and the connecting port and the connecting column are fixed to the first track. The role of the door and the second door. The first door is welded to the case; the second door is welded to the second heat sink. The power surge protector SPD is connected in parallel with the usual connection of the power line in the circuit. The bay is placed in the data center. Place the data center inside the inner shield. The first contact opening of the spiral conduit, the second contact opening of the conduit, and the outer portion are coated with a non-conductive insulating layer. The upper connection port of the power surge protector SPD is made of a conductive magnetic material.

1. Electromagnetic pulse defense system

The inner bracket is made of a conductive magnetically conductive metal, the first bracket is fixed to the inner surface of the inner shield, and the signal line and the control circuit protector are fixed on the first bracket; the first power surge protector is The SPD is fixed on the first bracket; the second bracket is fixed on the inner surface of the inner shield, and the second power surge protector SPD is fixed on the second bracket 515; the third bracket is fixed in the inner shield On the surface, the third power surge protector SPD is fixed to the third bracket. The fourth power surge protector SPD is fixed to the third bracket. The first shielding duct, the second shielding duct, the third shielding duct, the fourth shielding duct, the first air duct, and the second air duct are made of conductive magnetic metal and are mounted on the inner layer shield A catheter that is bent at 90°. The fourth grounding conductor on the third power surge protector SPD is the protective grounding wire PE of the third power surge protector (SPD) that drains the absorbed energy to the tank by connecting the inner surface of the inner shield. The seventh wire on the fourth power surge protector (SPD) is connected to the inner surface of the inner shield; the eighth wire on the fourth power surge protector (SPD) is connected to the inner surface of the inner shield; The fifth grounding conductor on the four-source surge protector (SPD) is connected to the inner surface of the inner shield; the fifth grounding conductor is the protective grounding PE of the fourth power surge protector (SPD), through the inner layer The inner surface of the shield is used to channel the absorbed energy to the tank.

The spiral conduit is installed at both ends of the first shielding conduit which is bent at 90° at both ends, and the first contact opening of the spiral conduit is connected with the third contact opening of the first shielding conduit; the first contact opening of the spiral conduit A fourth contact opening of a shielded conduit is connected. The signal line is connected in series with the signal line and the control line protector, and the first wire enters the spiral conduit from the second contact port of the spiral conduit, and then enters the first shielded conduit from the inside of the first contact port and the fourth contact port of the conduit The signal line enters the spiral conduit from the second contact opening of the spiral conduit, and then enters the first shielded conduit from the inside of the first contact port and the third contact port of the conduit; after the signal line enters the first shielded conduit, the signal enters The inner front shield and the first wire are connected to the first connection point; the signal wire and the second wire of the control circuit protector are connected to the line number line of the data center; the first ground line is a signal line, and the control line protector The protective ground wire PE is used to indirectly absorb the absorbed energy by connecting the inner surface of the inner shield. The signal line enters the spiral conduit from the second contact opening of the spiral conduit, and then enters the first shielded conduit from the inside of the first contact port and the third contact port of the conduit, and the second contact port of the spiral conduit and the power surge The upper connectors of the protector (SPD) are tightly connected together.

The spiral conduit is mounted at both ends of the second shielded conduit bent at 90° at both ends, the first contact opening is connected to the fifth contact opening of the second shielded conduit; the first contact of the spiral conduit and the second shielded conduit Six contact ports are connected. The power line is connected in parallel with the first power surge protector (SPD); the third wire enters the spiral conduit from the second contact opening of the spiral conduit and enters the sixth contact port of the first contact port and the second shielded conduit Into the second shielded conduit; the power cord enters the spiral conduit from the second contact opening of the spiral conduit and enters the second shielded conduit from the first contact port and the fifth contact port of the second shielded conduit; the power cord enters After the second shielding conduit enters the inner shield, the third conductor is connected in parallel with the third conductor. The power line is composed of an L line, an N neutral line, and a G protective ground line. The power line passes through the second shielded conduit and the spiral conduit through the second contact port, and the L line is connected to the first power interface of the data center. The N line is connected to the second power interface of the data center; the G protection ground line is connected to the inner surface of the second ground line, and the second ground line is the protective ground line PE of the second power surge protector (SPD) The energy absorbed by the inner shield is absorbed by connecting the inner surface of the inner shield. The third wire enters the spiral conduit from the second contact opening of the spiral conduit and then enters the second shield conduit from the sixth contact port of the first contact port and the second shield conduit, and the second contact port of the spiral conduit is The upper ports of the Power Surge Protector (SPD) are tightly connected together.

The first cooling water/liquid inlet and outlet conduit and the first contact port front portion of the spiral conduit are simultaneously placed into the third shielding conduit, and the fourth conductor enters the spiral conduit from the second contact opening of the spiral conduit and is first The contact port enters the third shielded conduit, and after the first cooling water/liquid inlet and outlet conduit enters the third shielded conduit, the fourth conductor is connected to the third shield before the entry into the inner shield and the second power surge protector (SPD) The third connection point inside the catheter. The third ground line is a protective ground wire PE of the second power surge protector (SPD), and the inner shield is used to guide the absorbed energy by connecting the inner surface of the inner shield. An outer layer of the spiral conduit is coated with an insulating layer to prevent the spiral conduit from contacting the first cooling water/liquid inlet and outlet conduit to cause a galvanic connection. After the fourth wire enters the spiral conduit from the second contact opening of the spiral conduit, the second contact opening of the spiral conduit is tightly coupled to the upper connection port of the power surge protector (SPD).

The second cooling water/liquid inlet and outlet conduit and the front portion of the first contact opening of the spiral conduit are simultaneously placed in the fourth shielding conduit, and the fifth conductor is inserted into the spiral conduit from the second contact opening of the spiral conduit and then the first contact The port enters the fourth shielded conduit, and after the second cooling water/liquid inlet and outlet conduit enters the fourth shielded conduit, the fifth conductor connected to the third power surge protector (SPD) is connected to the fourth shield before entering the inner shield. At the fourth connection point inside the conduit. The fourth ground line is a protective ground wire PE of the third power surge protector (SPD), and the inner shield is used to guide the absorbed energy by connecting the inner surface of the inner shield. An outer layer of the spiral conduit is coated with an insulating layer to prevent the spiral conduit from contacting the second cooling water/liquid inlet and outlet conduit to cause a current connection. The fifth wire enters the spiral conduit from the second contact opening of the spiral conduit and then enters the fourth shield conduit from the first contact port, and the second contact port of the spiral conduit and the upper portion of the power surge protector (SPD) The connectors are tightly connected together.

1.1. Working principle of electromagnetic pulse defense system:

1.1.1. The externally induced electromagnetic field penetrates the box and the current induced on the inner shield is passed by the fourth power surge protector (SPD) through the seventh conductor on the fourth power surge protector (SPD). And the eighth wire is absorbed. The external strong electromagnetic field is absorbed by the inner layer shield and the magnetic current is not saturated on the inner shield. The electromagnetic field cannot penetrate the inner shield shell and can not destroy the data center.

1.1.2. External strong electromagnetic field Because the spiral ducts installed at both ends of the first air duct and the second air duct cannot enter the inside in the form of electromagnetic field, only the current can be induced on the duct, and the current is induced on the duct. The current is absorbed by the fourth power surge protector (SPD) through the seventh and eighth conductors of the fourth power surge protector (SPD). The electromagnetic field cannot penetrate the inner shield body through the first air duct and the second air duct to achieve the purpose of destroying the data center.

1.1.3. External strong electromagnetic field The current induced on the signal line is intercepted by the signal line and the control line protector first connection point 503, and then absorbed by the signal line and the control line protector through the first wire. The current induced by the electromagnetic field cannot penetrate the inner shield housing through the signal line and cannot achieve the purpose of destroying the data center.

1.1.4. External strong electromagnetic field The current induced on the power line is intercepted by the first power surge protector second connection point 508, and is passed by the first power surge protector (SPD) through the first power surge protector. (SPD) third wire absorption. The current induced by the electromagnetic field cannot penetrate the inner shield housing through the power line and cannot achieve the purpose of destroying the data center.

1.1.5. External strong electromagnetic field The current induced on the first cooling water/liquid inlet and outlet conduit is intercepted by the third connection point, and is passed by the second power surge protector (SPD) through the second power surge protector (SPD). The fourth wire is absorbed. After the fourth wire passes through the inside of the spiral conduit, the current can only be induced to be absorbed by the second power surge protector (SPD) through the fourth wire of the second power surge protector, and cannot be induced inside the inner shield. magnetic field.

1.1.6. External strong electromagnetic field The current induced on the second cooling water/liquid inlet and outlet conduit is intercepted by the third connection point of the third power surge protector (SPD), and is used by the third power surge protector (SPD). Absorbed by the fifth conductor of the second power surge protector. After the fifth wire passes through the inside of the spiral conduit, only the current can be induced to be instantaneously absorbed by the third power surge protector (SPD) through the fifth power surge protector (SPD) fifth wire, and the inner shield is not possible. The magnetic field is induced internally.

All the above mouths, faces and lines that can be tapped by the electromagnetic field are effectively intercepted, and finally the external electromagnetic field is blocked outside the inner shield, and the data center can work normally in any electromagnetic environment.

2. Box structure: consists of a container body and an inner layer shield.

3. Blinds: Multiple louvers are placed around the two plenums of the cabinet, and the louvers can be selectively operated.

4. Electrical system: computer hardware is set in the box; data storage capacity department, data storage capacity department is electrically connected with computer hardware; interface electronic device, interface electronic device and computer hardware, and data storage capacity department electrical communication are constructed according to requirements and specifications .

5. Communication network: The network is coupled to a plurality of computing devices and an environmental system;

6. Controller: The controller is coupled to the humidifier and the plurality of computing devices via a network, the controller being operative to send instructions to the plurality of computing devices over the network, to receive the humidity signal, and to indicate the humidifier based on the received humidity signal Increase or decrease the humidity inside the container. A controller is coupled to the network, the controller being configured to communicate with the plurality of computing devices over the network to send instructions over the network to the at least one environmental system to instruct the at least one environmental system to change an environment within the enclosure.

7. Bracket: A computing device is housed on a cradle that can include a plurality of computing devices (eg, a blade server).

8. Vertical Cooling System: A cooling system controller that communicates with a vertical cooling system to receive environmental information for adjusting the internal environment within the shipping container. The vertical cooling system also includes means for coupling to the inlet valve and a temperature sensor.

The defensive electromagnetic pulse attack system of the container type data center provided by the invention forms a closed protective layer that the external electromagnetic field cannot penetrate according to the inner layer shielding body, and the electromagnetic pulse weapon explosion outside the intercepting box can be stereoscopically generated. The magnetic field protects the data center inside the shield, and the data center can work normally in any electromagnetic environment.

DRAWINGS

Figure 1 is a cross-sectional view showing the structure of the present invention.

Figure 2 is a perspective view of the present invention.

3 is a front cross-sectional view of the housing of the EMI electromagnetic attack system of the present invention.

4 is a side cross-sectional view of the housing of the EMI electromagnetic attack system of the present invention.

Fig. 5 is a schematic structural view of the present invention.

Figure 6 is a schematic view showing the shape of the weather strip of the present invention.

Figure 7 is a structural view of a casing and an inner shield of the present invention.

8 and 9 are structural views of the shield heat sink of the present invention.

Figure 10 is a perspective view of a screen door of the present invention.

Figure 11 is a circuit connection diagram of the present invention.

12 and 13 are views showing the internal structure of the bracket of the present invention.

Figure 14 is a perspective view of a data center of the present invention.

Figure 15 is an enlarged partial cross-sectional perspective view of the data center of the present invention.

Figure 16 is an electrical schematic of the electrical system of the data center of the present invention.

Figure 17 is a front elevational view of the cradle of the data center of the present invention.

Figure 18 is an enlarged partial cross-sectional perspective view of the data center of the present invention.

19 is an electrical schematic diagram of an electrical system of a data center of the present invention.

Figure 20 is an electrical schematic of the electrical system of the data center of the present invention.

Figure 21 is an enlarged partial cross-sectional perspective view of the data center of the present invention.

Figure 22 is a schematic diagram of the process of the signal line of the present invention entering the data center.

Figure 23 is a schematic illustration of the process of the power cord of the present invention entering the data center.

Figure 24 is a view of a spiral catheter of the present invention.

25 and 26 are structural views of the air duct of the present invention.

Figure 27 is an external front view of the power surge protector (SPD) of the present invention.

Figure 28 is a schematic illustration of the process of the first cooling water/liquid inlet and outlet conduit of the present invention entering the data center.

Figure 29 is a schematic illustration of the process of the second cooling water/liquid inlet and outlet conduit of the present invention entering the data center.

detailed description

In FIG. 1, FIG. 2 and FIG. 3, an inner layer shield 501 is disposed inside the casing 12, and a first heat dissipation plate 560 and a second heat dissipation plate are disposed on the inner layer shield body 501. 561, the first heat dissipation chamber 560 is provided with a first ventilation chamber 562; the second heat dissipation plate 561 is provided with a second ventilation chamber 563; and the inner layer shielding body 501 is provided with a data center 10. The inner shield 501 centers the first plenum 562 and the second plenum 563 on both sides of the cabinet 12 to form a complete modular container data center. The first heat dissipation plate 560 and the second heat dissipation plate 561 can effectively dissipate heat and conduct heat through the first ventilation chamber 562 and the second ventilation chamber 563. A first door 24 and a second door 557 are provided in the second ventilation protection chamber 563, and the first door 24 and the second door 557 are staggered and installed in a straight line.

In FIG. 1, FIG. 8, FIG. 24 and FIG. 25, the first heat dissipation plate 560 is composed of a plurality of first ventilation tubes 502 mounted thereon for guiding the hot air of the data center 10 to the first ventilation chamber 562; The fifth spiral conduit 613 is mounted at one end of the first air duct 502 bent at 90° at both ends, and the tenth contact port 614 of the fifth spiral duct 613 is connected to the seventh contact port 615 of the first air duct 502; The twelfth contact opening 630 of the six-spiral conduit 616 is coupled to the eighth contact opening 544 of the 502.

In FIG. 1, FIG. 9, FIG. 24 and FIG. 26, the second heat dissipation plate 561 is composed of a plurality of second ventilation tubes 525 mounted thereon for guiding the hot air of the data center 10 to the second ventilation chamber 563; The seventh spiral conduit 619 is mounted at one end of the second air duct 525 bent at 90° at both ends, and the thirteenth contact port 620 of the seventh spiral duct 619 is connected to the ninth contact port 545 of the second air duct 525; The fifteenth contact opening 623 of the fourteenth spiral conduit 622 is coupled to the tenth contact opening 546 of the second air duct 525.

In Fig. 3, a front cross-sectional view of the inner shield 501 of the electromagnetic pulse prevention system, the four included angles 540 are welded by a conductive magnetically conductive steel plate.

In Fig. 4, it is a side cross-sectional view of the inner shield 501 of the electromagnetic pulse prevention system, and the four included angles 540 are welded by a conductive magnetic steel plate.

In Fig. 6, a rubber sleeve 569 made of a conductive magnetically permeable rubber material has a rubber sleeve front portion 568 that is larger than the rubber sleeve rear portion 567.

In FIG. 7, the inner shield 501 is fixed to the casing 12 by a plurality of inner welds 547 and outer welds 544 or by inner screws 545 and outer screws 542, and the casing 12 is meant to include the inner shield 501. .

In FIGS. 10 and 6, the contact portion 565 is sheathed with a rubber sleeve 569 made of a conductive magnetic adhesive material, the rubber sleeve front portion 568 is larger than the rubber sleeve rear portion 567, and the first door 24 and the second door 557 are rear. The raised portion of 566 is for preventing electromagnetic field from entering. After the door leaf 599 of the first door 24 and the second door 557 is closed with the door frame 548, the rubber sleeve 569 is in close contact with the door frame contact portion 570 to form a conductive magnetic shielding body. . The connecting port 551 is composed of a connecting post 550 and a connecting port 551, which are regularly distributed around the door frame 548. The two adjacent connecting ports 551 are misaligned, respectively parallel to and perpendicular to the door frame 548, and connected to the door 551 and The connecting post 550 functions to fix the first door 24 and the second door 557. The first door 24 is welded to the case 12; the second door 557 is welded to the second heat sink 561.

In Figure 11, the power surge protector (SPD) is connected in parallel with the power line in the circuit.

In Figures 12, 13, 14, and 17, the cradle 70 is placed in the data center 10.

In FIGS. 14, 15, 18, and 21, the data center 10 is placed inside the inner layer shield 501.

In Fig. 24, the first contact opening 534 of the spiral conduit 535, the second contact opening 536 of the conduit, and the outer portion are coated with a non-conductive insulating layer 596.

In Fig. 27, the upper connection port 594 of the power surge protector (SPD) 593 is made of a conductive magnetically permeable metal material.

1. Electromagnetic pulse defense system

In FIG. 5, the first bracket 507 is fixed to the inner surface of the inner layer shield 501 by the inner layer shield 501 made of a conductive magnetically conductive metal, and the signal line and the control line protector 531 are fixed to the first bracket. 507; fix the first power surge protector (SPD) 506 on the first bracket 507; fix the second bracket 515 on the inner surface of the inner shield 501, and apply the second power surge protector (SPD) 516 is fixed on the second bracket 515; the third bracket 521 is fixed on the inner surface of the inner shield 501, and the third power surge protector (SPD) 592 is fixed on the third bracket 521. A fourth power surge protector (SPD) 522 is attached to the third bracket 521. The first shielding duct 532, the second shielding duct 509, the third shielding duct 511, the fourth shielding duct 519, the first air duct 502, and the second air duct 525 are made of conductive magnetically conductive metal and are shielded in the inner layer. The ends of the body 501 are bent into a 90° conduit. The fourth grounding conductor 591 on the third power surge protector (SPD) 592 is the protective grounding wire PE of the third power surge protector (SPD) 592, and is connected to the cabinet by connecting the inner surface of the inner layer shield 501. 12 to divert the absorbed energy. The seventh wire 524 on the fourth power surge protector (SPD) 522 is connected to the inner surface of the inner shield 501; the eighth wire 530 and the inner shield 501 on the fourth power surge protector (SPD) 522 The inner surface is connected; the fifth grounding conductor 523 on the fourth power surge protector (SPD) 522 is connected to the inner surface of the inner shield 501; the fifth grounding conductor 523 is the fourth power surge protector (SPD) The protective ground wire PE of 522 is used to guide the energy absorbed by the casing 12 by connecting the inner surface of the inner shield 501.

In FIGS. 5 and 22, the first spiral conduit 535 is mounted at one end of a first shield conduit 532 that is bent at 90[deg.] at both ends, the first contact opening 534 of the first spiral conduit 535 and the first shield conduit 532. The third contact port 600 is connected; the second spiral conduit 602 is mounted at one end of the first shielding conduit 532 bent at 90° at both ends, and the fourth contact opening 603 of the second spiral conduit 602 and the first shielding conduit 532 are The four contact ports 541 are connected. The signal line 504 is connected in series with the signal line and the control line protector (SPD) 531. The first wire 526 enters the second spiral conduit 602 from the third contact port 601 of the second spiral conduit 602, and is then contacted by the fourth contact of the conduit. The inside of the port 603 and the fourth contact opening 541 enters into the first shielding duct 532; the signal line 504 enters the first spiral duct 535 from the second contact port 536 of the first spiral duct 535, and then the first contact port of the duct The 534 and the third contact port 540 enter the first shielding duct 532; the signal line 504 enters the first shielding duct 532, and enters the inside of the inner shield 501 and is connected to the first connecting line 526 before the first connecting line 503; The signal line, the second wire 527 of the control line protector 531 is connected to the line number line 152 of the data center 10; the first ground line 533 is a signal line, a protective ground line (PE) of the control line protector (SPD) 531, The inner surface of the inner shield 501 is connected to the inner shield 501 to absorb the absorbed energy. The third contact opening 601 of the second spiral conduit 602 is tightly coupled to the upper connection port 594 of the power surge protector (SPD) 593.

In FIGS. 5, 11, and 23, the third spiral conduit 606 is mounted at one end of a second shield conduit 509 bent at 90[deg.] at both ends, and the fourth spiral conduit 610 is mounted at the ends bent at 90[deg.] One end of the second shielding duct 509, the fifth contact opening 608 is connected to the fifth contact opening 542 of the second shielding duct 509; the seventh contact opening 609 of the fourth spiral duct 610 and the sixth contact opening 543 of the second shielding duct 509 connection. The power line 510 is connected in parallel with the first power surge protector (SPD) 506, and the third wire 528 is entered by the seventh contact port 611 of the fourth spiral conduit 610 into the fourth spiral conduit 610 and then by the eighth contact port. The sixth contact port 543 of the second shielded conduit 509 enters the second shielded conduit 509; the power cord 510 enters the fourth spiral conduit 610 from the seventh contact opening 611 of the fourth spiral conduit 610, and then The eight contact ports 609 and the fifth contact opening 542 of the second shielded conduit 509 enter the second shielded conduit 509; The source line 510 enters the second shielded conduit 509 and is connected in parallel with the third lead 528 to the second connection point 508 before entering the interior of the inner shield 501. The power line 510 is composed of an L line, an N neutral line, and a G protection ground line. The power line 510 passes through the second shielding tube 509 and the fourth spiral duct 610 to pass through the seventh contact port 611 to separate the L line from the data center. The first power interface 112A is connected, the N line is connected to the second power interface 112B of the data center, and the second ground 547 is the protective ground (PE) of the second power surge protector (SPD) 516. The inner surface of the body 501 is directed to the inner shield 501 to dissipate the absorbed energy.

The third wire 528 enters the fourth spiral conduit 610 from the seventh contact opening 611 of the fourth spiral conduit 610 and enters the second shield through the eighth contact opening 609 of the eighth contact opening 609 and the second shielding conduit 509. After the conduit 509, the seventh contact opening 611 of the fourth spiral conduit 610 is tightly coupled to the upper connection port 594 of the power surge protector (SPD) 593.

In FIGS. 5 and 28, the first cooling water/liquid inlet and outlet conduit 513 and the front end of the eighteenth contact opening 626 of the ninth spiral conduit 624 are simultaneously placed into the third shielded conduit 511, and the fourth conductor 514 is The seventeenth contact opening 625 of the nine-spiral conduit 624 enters the ninth helical conduit 624 and enters the third shielded conduit 511 from the eighteenth contact opening 626. The first cooling water/liquid inlet and outlet conduit 513 enters the third shield. After the conduit 511, the fourth conductor 514 is connected to the third connection point 512 inside the third shield conduit 511 before entering the inner shield 501 and the second power surge protector (SPD) 516. The third ground line 516 is a protective ground line (PE) of the second power surge protector (SPD) 516, and the absorbed energy is dissipated to the inner shield 501 by connecting the inner surface of the inner shield 501. An insulating layer 596 is coated on the outside of the ninth spiral conduit 624 to prevent the ninth spiral conduit 624 from coming into contact with the first cooling water/liquid inlet and outlet conduit 513 to cause a current connection. After the fourth wire 514 enters the ninth spiral conduit 624 from the seventeenth contact port 625 of the ninth spiral conduit 624, the seventeenth contact port 625 of the ninth spiral conduit 624 and the power surge protector (SPD) 593 The upper connectors 594 are closely connected together.

In FIGS. 5 and 29, the front portions of the twentieth contact ports 629 of the second cooling water/liquid inlet and outlet conduit 520 and the tenth spiral conduit 627 are simultaneously placed in the fourth shielded conduit 519, and the fifth conductor 529 is tenth. The twentieth contact opening 629 of the spiral conduit 627 enters the tenth spiral conduit 627 and then enters the fourth shielded conduit 519 from the twentieth contact opening 629, and the second cooling water/liquid inlet and outlet conduit 520 enters the fourth shielded conduit After 519, the fifth conductor 529 entering the inner shield 501 and the third power surge protector (SPD) 592 is connected to the fourth connection point 518 inside the fourth shield conduit 519. The fourth ground line 591 is a protective ground line (PE) of the third power surge protector (SPD) 592, and the absorbed energy is dissipated to the inner shield 501 by connecting the inner surface of the inner shield 501. An insulating layer 596 is coated on the outside of the tenth spiral conduit 627 to prevent the tenth spiral conduit 627 from coming into contact with the second cooling water/liquid inlet and outlet conduit 520 to cause a current connection. The fifth wire 529 enters the tenth spiral conduit 627 from the nineteenth contact opening 628 of the tenth spiral conduit 627 and then enters the fourth shielded conduit 519 from the twentieth contact port 629, and the tenth spiral conduit 627 The nineteenth contact port 628 is tightly coupled to the upper connection port 594 of the power surge protector (SPD) 593.

2. Box structure

In FIGS. 12 and 13, in the interior 60 of the casing 12, a plurality of brackets 70 are disposed along the first longitudinal side portion 14 and the second longitudinal side portion 16. Supported by the first support member 50 on the laterally extending frame member 44, the first pair of spaced apart longitudinally extending supports the first bracket 56A and the second bracket 56B, supporting a plurality of brackets 70 extending along the first longitudinal side portion 14. . A second pair of spaced apart longitudinally extending support third brackets 58A and fourth brackets 58B supported by second support members 52 of laterally extending frame members 44 support a plurality of brackets 70 extending along second longitudinal sides 16. Above the third portion 54 of the laterally extending frame member 44, there is a central corridor 72 between the two brackets 70. In the central corridor 72, the third portion 54 of the laterally extending frame member 44 supports the walkway 74. The perforated portion 76 is fabricated from a gas permeable, porous material. The first wire management channel 78A and the second wire management channel 78B have an open top 82 and a movable cover 84 placed thereon.

In Figure 13, the bracket 70 is secured between the first longitudinal side portion 14 and the second longitudinal side portion 16 by an isolating coupling 86 on the first longitudinal side portion 14 and the canopy portion 30. The second upper plenum 90B is on the second longitudinal side portion 16 and the canopy portion 30. The air disposed in the first upper plenum 90A is cooled by the first vertical cooling system 100A. The air disposed in the second upper plenum 90B is cooled by the second vertical cooling system 100B. The cooled air flows downward from the first upper plenum 90A and the second upper plenum 90B into the central corridor 72 of the interior 60 of the casing 12 to the walkway 74. The first vertical cooling system 100A and the second vertical cooling system 100B enclose the central corridor 72 of the tank 12 between the brackets 70 in the interior 60 of the cabinet 12 with cooling air. The cooled air passes through the perforated portion 76 of the walkway 74 into the laterally extending lower plenum 46. Cooling air within the lower plenum 46 flows laterally along the laterally extending frame members 44 toward both the first longitudinal side 14 and the second longitudinal side 16. The cooled air is drawn up into the cradle 70, flows upward through the cradle 70, and returns to the first upper plenum 90A and the second upper plenum 90B above the cradle 70.

In FIGS. 14, 1 and 2, the first longitudinal side portion 14, the second longitudinal side portion 16, the fourth louver 18, the second end portion 20, the canopy portion 30, and the floor portion 32 pass the first The door 24 and the second door 557 can enter the interior 60 of the casing 12.

3, blinds

In FIG. 1, a second door 557 is disposed on the second heat insulation board 561 of the data main chamber 553, and the first louver 562 is provided with a first louver 552 and a second louver 555 at the left end end thereof. The third louver 556 is disposed on the upper, lower, left and right side walls; the fourth louver 18 is disposed at the right end of the second ventilating chamber 563, and the fifth louver 564 is disposed on the upper, lower, left and right side walls, in the fourth hundred The first door 24 is installed on the leaf window 18. The above ventilation design can effectively improve the heat dissipation effect and prevent the refrigeration unit from being damaged. The first louver 552, the second louver 555, the third louver 556, the fourth louver 18, and the fifth louver 564 can be selectively opened and closed, in the closed system state, All blinds are closed.

In FIG. 2, the case 12 has a first longitudinal side 14 opposite the second longitudinal side 16. The case 12 further includes a fourth louver 18, the first end extending laterally between the first longitudinal side portion 14 and the second longitudinal side portion 16; and the second end portion 20, the second end portion being The one side portion 14 and the second side portion 16 extend laterally therebetween. The first door 24 of the fourth louver 18, the case 12 further includes a top 30 that extends laterally between the first side portion 14 and the second side portion 16 at the fourth louver 18 and The two ends 20 extend longitudinally between each other. The casing 12 also includes a bottom portion 32 that extends laterally between the first side portion 14 and the second side portion 16 and extends longitudinally between the fourth louver 18 and the second end portion 20. The second end 20 includes a first louver 552 and a second louver 555.

4, electrical system

In FIGS. 16, 17, 18, and 19, first power line 112A and second power line 112B supply power to electrical system 110, which supplies power to computing device 102 mounted on cradle 70, electrical system 110 A first power distribution panel 120A and a second power distribution panel 120B are included. The first power distribution panel 120A has a plurality of circuit breakers 122A to M which are various types of live parts in the circuit breaker protection case 12. The second power distribution panel 120B has a plurality of circuit breakers 122A-N that protect various charging components within the housing 12. The first power line 112A is coupled to the electrical system 110 by means of a disconnect switch 124A, which is configured to The current of the power line 112A is selectively disconnected from the first power distribution panel 120A and the second power distribution panel 120B. The second power line 112B can be coupled to a separate disconnect switch 124B that is configured to selectively disconnect the current of the power line 112B. The first power distribution panel 120A provides power to the vertical cooling system 100A, and the second power distribution panel 120B provides power to the vertical cooling system 100B.

In Fig. 16, five brackets 70 extending along the first longitudinal side portion 14 of the casing 12 are: first bracket CARR. #1, second bracket CARR. #3, third bracket CARR.# 5. A fourth bracket CARR. #7 and a fifth bracket CARR. #9; five brackets 70 extending along the second longitudinal side portion 16 of the cabinet 12 are: a sixth bracket CARR. #0, Seven brackets CARR.#2, eighth bracket CARR.#4, ninth bracket CARR.#6 and tenth bracket CARR.#8. A plurality of electrical leads 130 are connected to the circuit breakers 122A-M of the first power distribution panel 120A and the circuit breakers 122A-N of the second power distribution panel 120B. Each electrical conductor 130 of the circuit breakers 122C-G and 122I-M coupled to the first power distribution panel 120A extends along the first longitudinal side 14 behind the bracket 70. Each of the electrical leads 130 of the circuit breakers 122C-G and 122I-M that are connected to the second power distribution panel 120B extends behind the bracket 70 along the second longitudinal side portion 16. Electrical leads 130 extending along the first longitudinal side 14 and the second longitudinal side 16 deliver electrical power to a plurality of electrical receptacles 132 that can be mounted to the first longitudinal side 14 and the second longitudinal side 16 or On the shelf 70.

In Figures 16, 19 and 20, each bracket 70 has a plurality of electrical receptacles 132 thereon.

In FIG. 17, the electrical outlet 132 for the tenth bracket CARR. #8 is coupled to the circuit breaker 122C of the first power distribution panel 120A and the second power distribution panel 120B by a pair of electrical conductors 130. The electrical receptacle 132 for the ninth bracket CARR. #6 is coupled to the circuit breaker 122D of the first power distribution panel 120A and the second power distribution panel 120B by a pair of electrical leads 130. The electrical outlet 132 for the eighth bracket CARR. #4 is coupled to the circuit breaker 122E of the first power distribution panel 120A and the second power distribution panel 120B by a pair of electrical conductors 130. The electrical outlet 132 for the seventh bracket CARR. #2 is coupled to the circuit breaker 122F of the first power distribution panel 120A and the second power distribution panel 120B by a pair of electrical conductors 130. The electrical outlet 132 for the sixth bracket CARR.#0 is coupled to the circuit breaker 122G of the first power distribution panel 120A and the second power distribution panel 120B by a pair of electrical conductors 130. Along the bracket 70 of the second longitudinal side portion 16, the electrical socket 132 for the fifth bracket CARR.#9 is coupled to the open circuit of the first power distribution panel 120A and the second power distribution panel 120B by a pair of electrical conductors 130 122I. The electrical outlet 132 for the fourth bracket CARR. #7 is coupled to the circuit breaker 122J of the first power distribution panel 120A and the second power distribution panel 120B by a pair of electrical conductors 130. The electrical outlet 132 for the third bracket CARR. #5 is coupled to the circuit breaker 122K of the first power distribution panel 120A and the second power distribution panel 120B by a pair of electrical conductors 130. The electrical outlet 132 for the second bracket CARR.#3 is coupled to the circuit breaker 122L of the first power distribution panel 120A and the second power distribution panel 120B by a pair of electrical conductors 130. The electrical outlet 132 for the first bracket CARR. #1 is coupled to the circuit breaker 122M of the first power distribution panel 120A and the second power distribution panel 120B by a pair of electrical conductors 130. Electrical system 110 can include a separate power source 133 for each electrical outlet 132. Each of the main power sources 133 can be coupled between one of the circuit breakers 122C-G and 122I-M of the first power distribution panel 120A and the second power distribution panel 120B and the electrical outlet 132.

Main power source 133 is coupled to controller 134. Controller 134 sends an instruction to main power source 133 to instruct these power sources to transmit power to one or more of their respective electrical outlets 132 by powering or stopping to one or more of their respective electrical outlets 132. Controller 134 controls which electrical outlets 132 are powered and which electrical outlets are not powered. The circuit breaker 122H of the first power distribution panel 120A is coupled to the vertical cooling system 100A by electrical conductors 130B, and the circuit breaker 122B of the second power distribution panel 120B is coupled to the vertical cooling system 100B by electrical conductors 130. The circuit breaker 122H of the second power distribution panel 120B can be coupled to the humidifier 123 by means of electrical leads 130. The humidifier 123 can include a humidity sensor configured to generate a humidity signal indicative of humidity within the tank 12. The controller 134 can be coupled to the optional humidifier 123 configured to receive the humidity signal to interpret the humidity signal to determine the humidity within the tank 12. The controller 134 can send an instruction to the humidifier 123 that the humidity signal indicates that the humidifier increases or decreases the humidity within the tank 12. In response to an instruction from the controller 134, the humidifier 123 can increase its water vapor output to increase the humidity inside the air within the tank 12 or reduce its output to reduce the humidity inside the air within the tank 12.

In FIGS. 18, 19, and 20, the UPS 114 includes one or more batteries 115. The UPS 114 provides power to the data center 10 when the power of the power line 112B is suddenly interrupted.

5, communication network

In Figures 15 and 18, data center 10 can include a network connection 150 coupled to external network 152 that can be connected to external network 152 by any suitable connection known in the art, including a wireless connection, a suitable connection Cable segment, fiber cable segment. The data center 10 can be coupled to an external network implemented in an adjacent building by means of one or more network cable connections. Data center 10 can also include an internal network or private network 154 for communicating data within data center 10 between various components of computing device 102. The private network 154 can be implemented as an Ethernet network. The network cable line is capable of coupling the computing devices 102 in the bay 70 to the various network components of the private network 154. The network cable line can include any suitable cable known in the art, including copper cables, fiber optic cables. The network cable line can be coupled along the first longitudinal side 14 and the second longitudinal side 16 as needed to effect connection to the computing device 102 residing in the cradle 70. The network cable line can reside within the wire management channels 78A and 78B.

Controller 134 is also coupled to a private network 154. Electrical system 110 is also capable of connecting to a dedicated network 154. Each main power source 133 can be coupled to a private network 154. Controller 134 can send commands to main power source 133 via dedicated network 154. The lighting system 140 can be coupled to a private network 154, and the controller 134 can send instructions to the lighting system 140 over the private network 154. Other components (eg, optional humidifier 123 and vertical cooling systems 100A and 100B) can be coupled to dedicated network 154, in communication with controller 134, and/or receiving instructions from controller 134. Network connection 150 can be coupled to private network 154 to provide communication between private network 154 and external network 152. Methods and apparatus for implementing a private network 154, coupling a computing device 102 to a private network 154, and coupling a private network 154 to an external network 152 are known in the art.

6, the controller

In FIG. 17, controller 134 is coupled to memory 136 and/or includes memory 136. Memory 136 includes instructions that can be executed by controller 134. The controller 134 can also be selectively coupled to one or more temperature sensors 137 disposed within the interior 60 of the cabinet 12, each of which is configured to transmit a temperature signal to the controller 134. The memory 136 can include instructions that, when executed by the controller 134, instruct the controller to interpret the temperature signals received from each of the temperature sensors 137 to obtain temperature measurements. Controller 134 is capable of controlling computing device 102 (see FIG. 17) and the environment within enclosure 12 via dedicated network 154. In embodiments in which the controller 134 is coupled to the network connection 150 to the external network 152, one or more remote computing devices coupled to the external network 152 can communicate with the controller 134. For example, the remote computing device can receive temperature information from the controller 134. Similarly, the remote computing device can receive humidity information from the controller 134 that is received by the controller from the optional humidifier 123. Remote computing device capable of transmitting The command is directed to controller 134 to instruct the controller to send an instruction to optional humidifier 123 to increase or decrease the humidity within housing 12. The remote computing device can also instruct the controller 134 to send an instruction such that the selected primary power source 133 is coupled to the selected electrical outlet 132 to power up or power down. The remote computing device can also instruct the controller 134 to turn the LEDs 142 of the lighting system 140 on or off.

In FIG. 17, controller 134 is capable of monitoring and/or controlling computing device 102, which can include instructions for monitoring UPS 114, various blade servers of computing device 102. The controller 134 can receive an instruction from the remote computing device to instruct the controller to turn a single component of the computing device 102 on or off, providing data to the remote computing device. The controller 134 can include a user interface 138 that is configured to display temperature measurements obtained from temperature signals received from each of the temperature sensors 137, as well as any data received from other systems within the enclosure 12.

7, bracket

In FIGS. 13 and 17, computing device 102 is placed on a cradle 70 that includes a plurality of computing device cradle 70 having an open bottom 210 opposite the open top 212. The bracket 70 has an open front portion 214, an open rear portion 216, and a computing device 102, a fan, a wire and cable line, a device mountable on the frame, and an accessory received in the open front portion 214. Cable and wiring wires, communication cables, can enter the cradle 70 through the rear portion 216, the rear portion being openable and/or capable of including one or more apertures 251 configured to allow one or more cables or wires to be It passes through. Electrical leads 130 and optional communication cable lines can extend along first longitudinal side portion 14 and second longitudinal side portion 16. The electrical receptacle 132 is positioned adjacent the rear portion 216 of the bracket 70 along the first longitudinal side portion 14 and the second longitudinal side portion 16. Such electrical outlets 132 and communication cable lines can be coupled to computing device 102 in the tray via rear portion 216 of bracket 70. The number of computing devices 102 housed within the interior 60 of the cabinet 12 is determined, at least in part, by the number of brackets 70 and the capacity of each tray housing the computing device 102. The cradle 70 includes a frame 220, a computing device 102, a fan, a cable line, a device mountable on the gantry, an accessory that can be mounted or otherwise attached to the frame. The frame 220 is configured to allow air to flow into the open bottom 210, upwardly through the cradle 70, through and around other items in the computing device 102 and its computing device, and out of the open top 212. The frame 220 includes a plurality of spaced upstanding support members 222A-H to define one or more upright device receiving regions 224A-C. There are three device receiving areas 224A-C that are comprised of four upright support members 222A-D disposed along the front portion 214 of the bracket 70 and four upright support members 222E disposed along the rear portion 216 of the bracket 70. ~H limited. The upstanding support members 222A-H are coupled together at the open top 212 of the bracket 70 by a vented top panel 226 having apertures 228A-F that communicate with the device receiving areas 224A-C through which heated air can exit The device receiving areas 224A-C are transferred to a first plenum 90A or a second plenum 90B positioned above the vented ceiling. The upright support members 222A-H are coupled together along the front portion 214 of the bracket 70 by the front rails 230 at the open bottom 210 along the rear portion 216 of the bracket 70 at the open bottom 210 by the rear rails 232. The four upright support members 222A-D aligned along the front portion 214 of the bracket 70 can be coupled to the four upright support members 222E-H aligned along the rear portion 216 of the bracket 70 by any desired number of front and rear extension members 236. Member 236 can provide structural stability to bracket 70.

In Figures 13 and 17, each of the plurality of air moving assemblies 260 has a plurality of air moving devices 264 that are oriented to blow air upward through the device receiving areas 224A-C, the air moving assemblies 260 being mounted The bracket 70 is between the standing support members 222A-H. Each air moving assembly 260 includes a frame 262 that is configured to be mounted within one of the device receiving areas 224A-C. The frame 262 houses a plurality of air moving devices 264, each of which is oriented such that air flows in substantially the same upward direction.

In Figures 13 and 17, the bracket 70 includes nine air moving assemblies 260. The number of air moving components installed within each of the device receiving areas 224A-C can be determined based, at least in part, on the amount of air circulation required to cool the computing device received therein. The air moving assemblies 260 each receive power from the electrical leads 130 that carry power to the cradle 70 to energize the computing device 102 housed therein. The erect device receiving areas 224A-C can be customized to receive a predetermined set of computing devices, and the erect device receiving areas 224A-C can be configured to receive the blade server 103 in a vertical orientation. A standard 19" rack mounted computer gear can be mounted inside the erect equipment receiving area 224A-C. A fan within the rack mounted computer gear draws air from the central corridor 72 of the interior 12 of the cabinet 12 to the erect equipment receiving area 224A- C. The air will pass through the rack mount computer gear, thereby being heated, exiting from the rack mounted computer gear adjacent the rear portion 216 of the bracket 70. The heated air can exit the bracket 70 or bracket 70 The rear portion 216 is mounted to the frame between the first longitudinal side portion 14 and the second longitudinal side portion 16 adjacent the longitudinal side portion. The air moving assembly 260 directs the heated air within the bracket 70 toward the bracket. The open top portion 210 of the 70 is directed upwardly. The air moving assembly 260 will assist in drawing heated air out of the bracket 70 and into the erect equipment receiving areas 224A-C, in which the air moves. The assembly 260 directs the heated air upward toward the open top 212 of the bracket 70. The rack mounted computer gears can be mounted into the upright equipment receiving areas 224A-C in any orientation. Rack Mount Computer Tooth The wheels can be mounted into the erector receiving areas 224A-C in a manner similar to a blade server. The rack mounted computer gears can be mounted to extend longitudinally within the housing 12. The isolation coupling 86 can be along the bottom 210 of the bracket 70. Coupled to the upright support members 222A-H. The isolation coupler 86 can also couple one or more of the upright support members 222E-H to the first longitudinal side 14 and the second longitudinal side 16 of the case 12.

In FIG. 16, an electrical outlet 132 coupled to a first power distribution panel 120A can be coupled to one of the rectifiers 242, and an electrical outlet 132 coupled to the second power distribution panel 120B can be coupled to other rectifiers in the rectifier 242. Each rectifier 242 receives power from a different power distribution panel first power distribution panel 120A or second power distribution panel 120B.

In FIG. 17, the two openings 240E and 240F each house a rectifier 242, and each of the four openings 240A-D houses a network switching device 244. Rectifier 242 can be configured to rectify from approximately 480V to approximately 48V.

In FIG. 17, the device receiving areas 224A-C can each be divided into four sections "S1-S4". The device receiving areas 224A-C are not limited to use with a blade server having a specific number of Ethernet ports. The device receiving areas 224A-C are not limited to use with a blade server having an Ethernet port, and can be used in conjunction with a blade server having other types of communication ports.

8, vertical cooling system

In FIG. 13 , the first vertical cooling system 100A cools air flowing upward through the bracket 70 disposed along the first longitudinal side portion 14 while the second vertical cooling system 100B is cooled through the second longitudinal side portion 16 The air that the carriage 70 flows upward. The second vertical cooling system 100B is substantially identical to the first vertical cooling system 100A.

In FIG. 13, the cooling water flow is transported by the first water line 318 to the tank 12 and transported away from the tank 12 by the second water line 320. The casing 12 includes a T-shaped inlet valve 330. The T-shaped inlet valve directs a portion of the flow of cooling water received from the first water line 318 to the first vertical cooling system 100A and the second vertical cooling system 100B. The tank 12 includes a T-shaped outlet valve 332 that directs the flow of cooling water received from both the first vertical cooling system 100A and the second vertical cooling system 100B to the second water line 320. The inlet tube 334 is coupled between an outlet of the inlet valve 330 and the water/refrigerant heat exchanger 300 of the second vertical cooling system 100B. The inlet tube 334 carries a portion of the cooling water stream to the water/refrigerant heat exchanger 300. A similar inlet tube is coupled between the other outlet of the inlet valve 330 and the water/refrigerant heat exchanger 300 of the first vertical cooling system 100A. An outlet pipe 336 is coupled between the water/refrigerant heat exchanger 300 of the second vertical cooling system 100B and one inlet of the outlet valve 332. The outlet tube 336 carries the cooling water stream from the water/refrigerant heat exchanger 300 to the outlet valve 332. A similar outlet tube is coupled between the water/refrigerant heat exchanger 300 of the first vertical cooling system 100A and the other inlet of the outlet valve 332. The inlet tube 334 and the water tray 340 together form a passive dehumidification system 350 that limits the humidity within the tank 12 without consuming more than the first vertical cooling system 100A and the second vertical cooling system 100B. Any additional electrical power. In the second vertical cooling system 100B, the coolant flow flows through the closed loop 352. The closed loop 352 includes a refrigerant supply manifold 354 and a refrigerant return manifold 356. The refrigerant supply manifold 354 delivers the cooled refrigerant to a plurality of supply tubes 360, each of which is connected to one of the plurality of refrigerant/air heat exchangers 370. Two heat exchangers 370 are provided for each of the brackets 70. A plurality of return conduits 372 are each coupled to one of a plurality of heat exchangers 370 that transport heated refrigerant from a plurality of heat exchangers 370 to a refrigerant return manifold 356, including for The two heat exchangers 370, the plurality of supply tubes 360, and the plurality of return tubes 372 of each of the brackets 70 each include ten conduits. The refrigerant return manifold 356 carries the heated refrigerant received from the heat exchanger 370 back to the water/refrigerant heat exchanger 300 to be cooled again by the flow of cooling water in the water/refrigerant heat exchanger 300. The refrigerant supply manifold 354, the supply tube 360, the refrigerant return manifold 356, and the return line 372 can each include one or more flow regulators or valves 358 configured to control or limit the flow of refrigerant therethrough.

In Figures 13 and 14, each heat exchanger 370 is implemented as a radiator type evaporator, and the coil assembly 373 of the heat exchanger is disposed at an angle relative to the front portion 214 of the bracket 70 and the open top portion 212. The coil assembly 373 has one or more cooling surfaces at which heat exchange between the air outside the coil assembly 373 and the refrigerant flowing within the coil assembly 373. The coil assembly 373 of the heat exchanger 370 can be angled to maximize the number of cooling surfaces available for locating the space of the heat exchanger, thereby providing a maximum amount of cooling capacity. The internal angle "A" defined between the front portion 214 of the bracket 70 and the coil assembly 373 can vary from about 144 degrees to about 158 degrees. An angle from about 144 degrees to about 158 degrees can be defined between the coil assembly 373 and the open top 212 of the bracket 70. A plurality of elbows or curved conduits 390 can be coupled between each heat exchanger 370 and at least a portion of the open top 212 of an adjacent bracket 70 to direct heated air raised from the bracket 70 to the heat In exchanger 370, a curved conduit 390 is coupled to a single heat exchanger 370 and a portion of the open top 212 of an adjacent bracket 70. Each curved conduit 390 has a bend 392 that defines a curved travel path for heated air that is driven out of the carrier 70 into the heat exchanger 370. The curved portion 392 helps to prevent the canopy portion 30 in the upper first plenum 90A and the second plenum 90B by the heated air rising from the bracket 70 being guided along the canopy portion 30 of the casing 12. A back pressure is created that pushes the heated air back into the open top 212 of the bracket 70. The curved conduit 390 includes an internal baffle 394 that branches the curved conduit 390 along a curved travel path. Sealing member 396 is positioned between rear portion 216 of bracket 70 and first longitudinal side portion 14 and second longitudinal side portion 16, and sealing member 397 is positioned between front portion 214 of bracket 70 and heat exchanger 370.

In Figure 13, each of the brackets 70 includes an air moving device 264 that is consumed by the air moving device 264 to substantially cool the amount of power of the computing device 102 can be at least partially caused by how air flows from the carrier 70 into the heat exchanger Determined in 370. The shape of the curved conduit 390 in the upper first plenum 90A and the second plenum 90B is determined by the amount of power consumed by the air moving device 264. The curved conduit 390 can be configured to minimize the amount of power consumed by the air moving device 264.

In Figure 14, each heat exchanger 370 has a coil assembly 373. Refrigerant flows from supply line 360 into each heat exchanger 370 and circulates through its coil assembly 373. The air above the cradle 70 is hot because it has been heated by the computing device 102. The heated air travels upward through heat exchanger 370 to be cooled by the refrigerant.

In Figure 17, the case 12 is positioned in an environment in which the air outside the container has an environment suitable for cooling the temperature of the computing device 102 mounted within the cradle 70, then the container can include an opening from which air from the external environment can Flow through the opening into the container to cool the computing device 102. The container can also include an opening through which air heated by computing device 102 can exit the container and enter the external environment. The amount of power consumed by the air moving device 264 to cool the computing device 102 can be determined, at least in part, by how air flows from the cradle 70 into the heat exchanger 370. The power of the computing device 102 is cooled by the air moving device 264 as determined by the amount of air flowing from the cradle 70 into the heat exchanger 370.

In FIG. 21, the refrigerant supply manifold 354 includes a valve 358 prior to the first supply tube 360 that regulates the flow of refrigerant into the supply tube 360. Supply tubes 360 each include a valve 358 that regulates the flow of refrigerant to each heat exchanger 370. The amount of cooling supplied to each heat exchanger 370 can be adjusted by selectively adjusting the flow of refrigerant through the valve 358. The second vertical cooling system 100B can include one or more sensors 376 coupled to a refrigerant supply manifold 354, a supply tube 360, a refrigerant return manifold 356, and/or a return conduit 372. Each temperature sensor 376 can be used to monitor the temperature of the refrigerant stream to produce a temperature signal. The second vertical cooling system 100B can include a cooling system controller 380 that can be coupled to the inlet valve 330 and the temperature sensor 376.

In Figure 21, the second vertical cooling system 100B includes two fluid streams, a refrigerant stream, a cold water, or a cooling water stream. In the second vertical cooling system 100B, the refrigerant stream is cooled by transferring its heat to the cooling water stream. The second vertical cooling system 100B includes a water/refrigerant heat exchanger 300 configured to transfer heat from the refrigerant stream to the cooling water stream. The cooling water stream is received from an externally cooled water supply system or water source 310 that is a continuous cooling water stream. The cooling water flow can reside in a closed circuit 312 that returns the heated previous cooling water to the external cooling water source 310 for further cooling. The closed circuit 312 and the water/refrigerant heat exchanger 300 are spaced apart from the carrier 70 to which the refrigerant is carried. The closed circuit 312 of the cooling water flow and the water/refrigerant heat exchanger 300 are isolated from the computing device 102 of the data center 10.

Claims (4)

1. A containerized data center defense electromagnetic pulse attack system, characterized in that: in the inner layer shield (501), the signal line, the control line protector (531) and the signal line (504) are connected in series; the first power wave The third wire (528) of the surge protector SPD (506) is connected in parallel with the power line (510); the fourth power surge protector SPD (522) is connected to the inner shield (501), and each of the above connections depends on the inner layer The shield (501) constitutes a protective layer that is not permeable to external electromagnetic fields, protecting the data center (10) within the inner shield (501).
2. A containerized data center defense electromagnetic pulse attack system, characterized in that: in the inner layer shield (501), the signal line, the control line protector (531) and the signal line (504) are connected in series; the first power wave The surge protector SPD (506) is connected in parallel with the power line; the fourth power surge protector SPD (522) is connected to the inner shield, the second power surge protector SPD (516) and the first coolant/water conduit The connection (513) is connected; the third power surge protector SPD (592) is connected to the second coolant/water conduit (520), and the inner shield (501) forms a closed external electromagnetic field impenetrable protection. The layer protects the data center (10) of the inner shield (501). The defensive electromagnetic pulse attack system of the containerized data center consists of the following systems and devices: electromagnetic pulse defense system, cabinet structure, blinds, electrical systems, communication Network, controller, bay and vertical cooling system.
3. The defensive electromagnetic pulse attack system of a containerized data center according to claim 2, wherein the first bracket (507) is fixed in the inner shield (501) made of a conductive magnetically conductive metal. The inner surface of the layer shield (501), the signal line and the control line protector (531) are fixed on the first bracket (507); and the first power surge protector SPD (506) is fixed on the first bracket (507) Fixing the second bracket (515) on the inner surface of the inner shield (501), fixing the second power surge protector SPD (516) to the second bracket (515); and placing the third bracket ( 521) fixed on the inner surface of the inner shield (501), the third power surge protector SPD (592) is fixed on the third bracket (521), and the fourth power surge protector SPD (522) Fixed on the third bracket (521), the first shielding conduit (532), the second shielding conduit (509), the third shielding conduit (511), the fourth shielding conduit (519), the first ventilation tube (502), The second air pipe (525) is made of a conductive magnetic metal and is mounted on the inner shield (501) at both ends to be bent at 90°, and the third power surge protector is on the SPD (592). fourth The ground wire (591) is a protective ground wire PE of the third power surge protector SPD (592), and the absorbed energy is diffused to the casing (12) by connecting the inner surface of the inner shield (501), the fourth power source The seventh wire (524) on the surge protector SPD (522) is connected to the inner surface of the inner shield (501); the eighth wire (530) and the inner layer on the fourth power surge protector SPD (522) The inner surface of the shield (501) is connected; the fifth ground conductor (523) on the fourth power surge protector SPD (522) is connected to the inner surface of the inner shield (501); the fifth ground conductor (523) The protective ground wire PE of the fourth power surge protector SPD (522) is used to guide the absorbed energy to the casing (12) by connecting the inner surface of the inner shield (501), and the first spiral conduit 535 is mounted on One end of the first shielding duct 532 bent at 90° at both ends, the first contact opening 534 of the first spiral duct 535 is connected to the third contact port 600 of the first shielding duct 532; the second spiral duct 602 is installed in two One end of the first shielding duct 532 bent at 90°, and the fourth contact opening 603 of the second spiral duct 602 are connected to the fourth contact opening 541 of the first shielding duct 532, The signal line 504 is connected in series with the signal line and the control line protector (SPD) 531. The first wire 526 enters the second spiral conduit 602 from the third contact port 601 of the second spiral conduit 602, and is then contacted by the fourth contact of the conduit. The inside of the port 603 and the fourth contact opening 541 enters into the first shielding duct 532; the signal line 504 enters the first spiral duct 535 from the second contact port 536 of the first spiral duct 535, and then the first contact port of the duct The 534 and the third contact port 540 enter the first shielding duct 532; the signal line 504 enters the first shielding duct 532, and enters the inside of the inner shield 501 and is connected to the first connecting line 526 before the first connecting line 503; The second wire 527 of the signal line and control line protector 531 is connected to the line number line 152 of the data center 10; the first ground line 533 is the signal line, and the protective ground line (PE) of the control line protector (SPD) 531 is second. The third contact opening 601 of the spiral conduit 602 is tightly coupled to the upper connection port 594 of the power surge protector (SPD) 593, and the third spiral conduit 606 is mounted to the second shielded conduit 509 which is bent at 90[deg.] at both ends. One end of the fifth spiral conduit 606 fifth contact 608 is connected to the fifth contact opening 542 of the second shielded conduit 509; the fourth spiral conduit 610 is mounted at one end of the second shielded conduit 509 bent at 90[deg.] at both ends, and the seventh contact 609 of the fourth spiral conduit 610 Connected to the sixth contact port 543 of the second shielded conduit 509, the power line 510 is connected in parallel with the first power surge protector (SPD) 506, and the third wire 528 is connected to the seventh contact port 611 of the fourth spiral conduit 610. Entering the fourth spiral conduit 610 and entering the second shielding conduit 509 by the eighth contact opening 609 and the sixth contact opening 543 of the second shielding conduit 509; the power cord 510 is contacted by the seventh contact of the fourth spiral conduit 610 The port 611 enters the fourth spiral conduit 610, and then enters the second shielded conduit 509 by the eighth contact port 609 and the fifth contact port 542 of the second shielded conduit 509; after the power cord 510 enters the second shielded conduit 509, Before entering the inner shield 501, the third wire 528 is connected in parallel to the second connection point 508. The power line 510 is composed of an L line, an N neutral line and a G protection ground. The power line 510 passes through the second shielded conduit 509. And the fourth spiral conduit 610 is worn out by the seventh contact opening 611 The L-line is connected to the first power interface 112A of the data center, the N-line is connected to the second power interface 112B of the data center, and the second ground 547 is the protective ground of the second power surge protector (SPD) 516 (PE) The third wire 528 enters the fourth spiral conduit 610 from the seventh contact opening 611 of the fourth spiral conduit 610 and enters the sixth contact port 609 of the second shielded conduit 509 and the sixth contact opening 543 of the second shielded conduit 509. After the second shielded conduit 509, the seventh contact opening 611 of the fourth spiral conduit 610 is tightly coupled to the upper connection port 594 of the power surge protector (SPD) 593, the first cooling water/liquid inlet and outlet conduit 513 and the ninth. The front end of the eighteenth contact opening 626 of the spiral conduit 624 is simultaneously placed into the third shielded conduit 511, and the fourth lead 514 is entered into the ninth helical conduit 624 by the seventeenth contact opening 625 of the ninth helical conduit 624. Then, the 18th contact port 626 enters the third shielded conduit 511, and after entering the third shielded conduit 511, the first cooling water/liquid inlet and outlet conduit 513 enters the front shield 501 and the second power surge protector ( The SPD) 516 fourth wire 514 is connected to the third inside the third shielded conduit 511 Contact 512, the third ground line 516 is the protective ground (PE) of the second power surge protector (SPD) 516, and the outer layer of the ninth spiral conduit 624 is coated with an insulating layer 596 to prevent the ninth spiral conduit 624. Contact with the first cooling water/liquid inlet and outlet conduit 513 to cause a current connection. After the fourth wire 514 enters the ninth spiral conduit 624 from the seventeenth contact port 625 of the ninth spiral conduit 624, the ninth spiral conduit 624 The seventeen contact port 625 is tightly coupled to the upper port 594 of the power surge protector (SPD) 593, and the second cooling water/liquid inlet and outlet conduit 520 and the twentieth contact port 629 of the tenth spiral conduit 627 are front. Simultaneously placed in the fourth shield conduit 519, the fifth conductor 529 enters the tenth spiral conduit 627 from the twentieth contact port 629 of the tenth spiral conduit 627 and enters the fourth shield conduit from the twentieth contact port 629. In 519, after the second cooling water/liquid inlet and outlet conduit 520 enters the fourth shielding conduit 519, the fifth conductor 529 of the third power surge protector (SPD) 592 is connected to the fourth shielded conduit before entering the inner shield 501. At the fourth connection point 518 inside the 519, the fourth ground line 591 is the third power. The protective earth (PE) of the surge protector (SPD) 592 is coated with an insulating layer 596 on the outside of the tenth spiral conduit 627 to prevent the tenth spiral conduit 627 from contacting the second cooling water/liquid inlet and outlet conduit 520. When the current is connected, the fifth wire 529 enters the tenth spiral conduit 627 from the nineteenth contact opening 628 of the tenth spiral conduit 627 and enters the fourth shielded conduit 519 from the twentieth contact port 629, the tenth spiral The nineteenth contact opening 628 of the conduit 627 is tightly coupled to the upper connection port 594 of the power surge protector (SPD) 593.
4. The defensive electromagnetic pulse attack system of a containerized data center according to claim 2, wherein the defensive electromagnetic pulse attack system of the container data center is composed of the following system and device, an electromagnetic pulse defense system, a box structure, a blind, Electrical system, communication network, controller, bracket and vertical cooling system, in the interior (60) of the casing (12), a plurality of brackets (70) along the first longitudinal side (14) and the second longitudinal side The portion (16) is disposed, supported by the first support member (50) on the laterally extending frame member (44), the first pair of spaced apart longitudinally extending supports the first bracket (56A) and the second bracket (56B), supported a plurality of brackets (70) extending along the first longitudinal side portion (14), a second pair of spaced apart longitudinally extending support third brackets supported by the second support members (52) of the laterally extending frame members (44) 58A) and fourth bracket (58B) support a plurality of brackets (70) extending along the second longitudinal side portion (16) above the third portion (54) of the laterally extending frame members (44), the two brackets Between (70) there is a central corridor (72) in which the third portion (54) of the laterally extending frame member (44) supports the walkway (74) and the perforated portion (76) is permeable and porous The material is manufactured, a first wire management channel (78A) and a second wire management channel (78B) having an open top (82) and a movable cover (84) placed thereon, the bracket (70) being isolated The device (86) is fixed between the first longitudinal side portion (14) and the second longitudinal side portion (16), the first upper venting chamber (90A) at the first longitudinal side portion (14) and the canopy portion (30) Above, the second upper plenum (90B) is on the second longitudinal side (16) and the canopy (30), and the air disposed in the first upper plenum (90A) is controlled by the first vertical cooling system (100A) Cooling, disposed in the second upper plenum (90B) The gas is cooled by the second vertical cooling system (100B), and the cooled air flows downward from the first upper venting chamber (90A) and the second upper venting chamber (90B) to the interior (60) of the tank (12). In the central corridor (72), the flow to the walkway (74), the first vertical cooling system (100A) and the second vertical cooling system (100B) allow the box (12) to be in the box between the brackets (70) The central corridor (72) of the interior (60) of the body (12) is filled with cooling air that passes through the perforations (76) of the aisle (74) into the laterally extending lower plenum (46), the lower plenum ( The cooling air in 46) flows laterally along the laterally extending frame members (44) toward both the first longitudinal side portion (14) and the second longitudinal side portion (16), and the cooled air is drawn up to the bracket (70). , flowing upward through the bracket (70), returning to the first upper plenum (90A) and the second upper venting chamber (90B) above the bracket (70), the first longitudinal side (14), the first Two longitudinal side portions (16), a fourth louver (18), a second end portion (20), a canopy portion (30) and a floor portion (32) passing through the first door (24) and the second door (557) can enter the interior (60) of the cabinet (12) in the data host A second door (557) is disposed on the second heat insulation panel (561) of the (553), and the first louver (552) is provided with a first louver (552) and a second louver (555). a third louver (556) is disposed on the upper, lower, left and right side walls; a fourth louver (18) is disposed at a right end of the second ventilating chamber (563), and a fifth is disposed on the upper, lower, left and right side walls The shutter (564), the first door (24) is installed on the fourth louver (18), the above ventilation design can effectively improve the heat dissipation effect and prevent the refrigeration unit from being damaged, the first louver (552) The second louver (555), the third louver (556), the fourth louver (18), and the fifth louver (564) can be selectively opened and closed in the closed system state In the middle, all the louvers are closed, and the box body (12) has a first longitudinal side portion (14) opposite to the second longitudinal side portion (16), the box body (12) further comprising: a fourth louver (18), a first end laterally extending between the first longitudinal side portion (14) and the second longitudinal side portion (16); and a second end portion (20) having a second end portion at the first side portion (14) and The second side portion (16) extends laterally between the first side door (24) of the fourth louver (18), The body (12) further includes a top portion (30) extending laterally between the first side portion (14) and the second side portion (16) at the fourth louver (18) and the second end portion Longitudinally extending between (20), the casing (12) further includes a bottom portion (32) extending laterally between the first side portion (14) and the second side portion (16) at the fourth portion A longitudinal extension between the louver (18) and the second end (20), the second end (20) comprising a first louver (552) and a second louver (555), the first power line ( 112A) and a second power line (112B) supplying power to the electrical system (110), the electrical system (110) supplying power to a computing device (102) mounted on the cradle (70), the electrical system (110) including the first The electric panel (120A) and the second power distribution panel (120B), the first power distribution panel (120A) has a plurality of circuit breakers (122A-M), and the various charging parts in the circuit breaker protection box (12), The second distribution panel (120B) has a plurality of circuit breakers (122A-N) that protect various charging components within the housing (12), and the first power line (112A) is coupled to the disconnecting switch (124A) to Electrical system (110), the disconnect switch (124A) is configured to draw current from the power line (112A) The first power distribution panel (120A) and the second power distribution panel (120B) are selectively disconnected, and the second power line (112B) can be coupled to a separate disconnect switch (124B) configured to For selectively disconnecting the current of the power line (112B), the first power distribution panel (120A) provides power to the vertical cooling system (100A) and the second power distribution panel (120B) provides power to the vertical cooling system (100B) Power, five brackets (70) extending along the first longitudinal side (14) of the casing (12) are: first bracket CARR. #1, second bracket CARR. #3, third bracket CARR.#5, fourth bracket CARR.#7 and fifth bracket CARR.#9; five brackets (70) extending along the second longitudinal side (16) of the box (12) are: Six brackets CARR.#0, seventh bracket CARR.#2, eighth bracket CARR.#4, ninth bracket CARR.#6 and tenth bracket CARR.#8, multiple electrical wires (130 The circuit breakers (122A-M) connected to the first power distribution panel (120A) and the circuit breakers (122A-N) of the second power distribution panel (120B) are coupled to the first power distribution panel (120A) Each of the electrical leads (130) of the circuit breakers (122C-G) and (122I-M) extends along the first longitudinal side (14) behind the bracket (70) and is connected Each of the electrical conductors (130) of the circuit breakers (122C-G) and (122I-M) to the second power distribution panel (120B) extends along the second longitudinal side (16) behind the bracket (70). Electrical leads (130) extending along the first longitudinal side (14) and the second longitudinal side (16) deliver power to a plurality of electrical outlets (132) that are mountable to the first longitudinal side (14) And a second longitudinal side (16) or bracket (70), each bracket (70) having a plurality of electrical sockets (132) for electrical sockets of the tenth bracket CARR.#8 (132) a circuit breaker (122C) coupled to the first power distribution panel (120A) and the second power distribution panel (120B) by a pair of electrical conductors (130) for the electrical socket of the ninth bracket CARR.#6 ( 132) A circuit breaker (122D) coupled to the first distribution panel (120A) and the second distribution panel (120B) by a pair of electrical leads (130) for electrical sockets of the eighth bracket CARR.#4 (132) A circuit breaker (122E) coupled to the first distribution panel (120A) and the second distribution panel (120B) by a pair of electrical conductors (1300), an electrical socket for the seventh bracket CARR.#2 (132) A circuit breaker (122F) coupled to the first distribution panel (120A) and the second distribution panel (120B) by a pair of electrical leads (130) The electrical socket (132) for the sixth bracket CARR.#0 is coupled to the circuit breaker (122G) of the first power distribution panel (120A) and the second power distribution panel (120B) by a pair of electrical wires (130) ), along the bracket (70) of the second longitudinal side (16), the electrical socket (132) for the fifth bracket CARR.#9 is coupled to the first power distribution panel by a pair of electrical leads (130) (120A) and the second distribution panel (120B) circuit breaker (122I), the electrical socket (132) for the fourth bracket CARR.#7 is coupled to the first power distribution via a pair of electrical leads (130) The circuit breaker (122J) of the panel (120A) and the second power distribution panel (120B), and the electrical socket (132) for the third bracket CARR.#5 are coupled to the first one by a pair of electrical wires (130) A circuit breaker (122K) of the electrical panel (120A) and the second power distribution panel (120B), and an electrical socket (132) for the second bracket CARR.#3 are coupled to the first through a pair of electrical leads (130) The circuit breaker (122L) of the power distribution panel (120A) and the second power distribution panel (120B), the electrical socket (132) for the first bracket CARR.#1 is coupled to the first through a pair of electrical wires (130) A power distribution panel (120A) and a second power distribution panel (120B) circuit breaker (122M), the electrical system (110) can be included for each power A separate power source (133) of the socket (132), each of the main power sources (133) being connectable to the circuit breakers (122C-G) of the first power distribution panel (120A) and the second power distribution panel (120B) and Between one of (122I-M) and the electrical outlet (132), the main power source (133) is coupled to the controller (134), and the controller (134) sends an instruction to the main power source (133) to indicate these power directions. One or more of its respective electrical outlets (132) transmit power to one or more of its respective electrical outlets (132) by power or stop, and the controller (134) controls which electrical outlets (132) are powered and Which electrical outlets are not powered, the circuit breaker (122H) of the first power distribution panel (120A) is coupled to the vertical cooling system (100A) by means of electrical leads (130), and the circuit breaker of the second power distribution panel (120B) ( 122B) is coupled to the vertical cooling system (100B) by means of electrical leads (130), and the circuit breaker (122H) of the second distribution panel (120B) can be coupled to the humidifier (123) by means of electrical leads (130), The humidifier (123) can include a humidity sensor configured to generate a humidity signal indicative of humidity within the tank (12), the controller (134) being coupled to the optional humidifier (123) Having received the humidity signal to interpret the humidity signal to determine the humidity within the tank (12), the controller (134) can send a command to the humidifier (123) indicating the humidifier to increase or decrease the tank (12) Humidity, in response to an instruction from the controller (134), the humidifier (123) can increase its water vapor output to increase the humidity inside the air in the tank (12) or reduce its output to reduce Small box (12) The humidity inside the air, the UPS 114 includes one or more batteries (115), the power of the power line (112B) is suddenly interrupted, the UPS 114 provides power to the data center (10), and the data center (10) can include the external network (152) A network connection (150), the network connection (150) can be connected to the external network (152) by any suitable connection known in the art, including a wireless connection, a copper cable segment, a fiber optic cable segment, and a data center ( 10) Capable of being coupled to an external network implemented in a neighboring building by means of one or more network cable connections, the data center (10) can also comprise an internal network or a private network (154) for internal data or private networks Data within the center (10) is transferred between various components of the computing device (102), the private network (154) can be implemented as an Ethernet network, and the network cable line can couple the computing devices (102) in the cradle (70) To the various network components of the private network (154), the network cable lines can include any suitable cable known in the art, including copper cables, fiber optic cables, and network cable lines that can be routed as needed A longitudinal side portion (14) and a second longitudinal side portion (16) are coupled to effect connection to a computing device (102) residing in the cradle (70), the network cable line being capable of residing in the wire management channel ( 78A) and (78B), the computing device (102) in the cradle (70) can be coupled to a single component of the private network (154) by means of a wireless connection, the controller (134) also coupled to the private network (154), The electrical system (110) is also connectable to a private network (154), each primary power source (133) (coupled to an electrical outlet (132)) can be coupled to a private network (154), and the controller (134) can be dedicated The network (154) sends instructions to the main power source (133), the lighting system (140) can be coupled to a private network (154), and the controller (134) can send commands to the lighting system (140) via the private network (154), other components Capable of being coupled to a private network (154), communicating with and/or receiving instructions from a controller (134), the network connection (150) being capable of being coupled to a private network (154), over the private network (154) and external Communication is provided between networks (152), controller (134) is coupled to memory (136) and/or includes memory (136), and memory (136) includes The controller (134) is also capable of being selectively coupled to one or more temperature sensors (137) disposed within the interior (60) of the housing (12) for the commands executed by the controller (134). Each is configured to send a temperature signal to a controller (134), which can include instructions that, when executed by the controller (134), instruct the controller to interpret receipt from each temperature sensor (137) The temperature signal is obtained to obtain a temperature measurement, and the controller (134) is capable of controlling the computing device (102) and the environment within the cabinet (12) through a dedicated network (154), the controller (134) being coupled to In an embodiment of the network connection (150) of the external network (152), one or more remote computing devices coupled to the external network (152) can communicate with the controller (134), the remote computing device capable of transmitting instructions to the controller (134), thereby instructing the controller to send an instruction to the optional humidifier (123) to increase or decrease the humidity within the tank (12), the remote computing device being further capable of instructing the controller (134) to send an instruction, thereby Causing the selected main power source (133) to be coupled to the selected one The electrical outlet (132) is powered up or powered down, and the remote computing device can also instruct the controller (134) to turn the LED 142 of the illumination system (140) on or off, the controller (134) being capable of monitoring and/or controlling the computing device (102) The memory (136) can include instructions for monitoring the UPS 114, the various blade servers of the computing device (102), and the controller (134) can receive instructions from the remote computing device to instruct the controller to calculate the device (102) The individual components are turned "on" or "off" to provide data to the remote computing device, and the controller (134) can include a user interface (138) configured to display the temperature signals received from each of the temperature sensors (137) The temperature measurement, and any data received from other systems within the housing (12), the computing device (102) is placed on the cradle (70), and the computing device (102) includes a plurality of computing device cradle (70) An open bottom (210) opposite the open top (212), the bracket (70) has an open front portion (214), an open rear portion (216), a computing device (102), a fan, a wire and cable line, and can be mounted Equipment and accessories on the rack are received at the open front (21 4), the cable and wiring wires, the communication cable, can enter the bracket (70) through the rear portion (216), the rear portion can be opened and/or can include one or more holes (251), the hole configuration One or more cables or wires are allowed to pass therethrough, and the electrical wires (130) and optional communication cable lines can extend along the first longitudinal side (14) and the second longitudinal side (16), the electrical socket (132) Between the first longitudinal side portion (14) and the second longitudinal side portion (16) positioned adjacent to the rear portion (216) of the bracket (70), such an electrical socket (132) and communication cable line can pass through the bracket The rear portion (216) of (70) is coupled to the computing device (102) in the cradle, and the number of computing devices (102) housed within the interior (60) of the cabinet (12) is at least partially supported by The number of shelves (70) and the capacity of each tray housing the computing device (102) determines that the carrier (70) includes a frame (220), a computing device (102), a fan, a cable line, and can be mounted on the rack. The device, accessory can be mounted or otherwise attached to the frame, and the frame (220) is configured to allow air to flow into the open bottom (210), upwardly through the bracket (70), through and around Around the computing device (102) and other items in its computing device, and out of the open top (212), the frame (220) includes a plurality of spaced upstanding support members (222A-H) to define one or more upright devices Receiving areas (224A-C) having three device receiving areas (224A-C), the device receiving areas being provided by four upright support members (222A-D) disposed along the front portion (214) of the bracket (70) and Four upright support members (222E-H) are provided along the rear portion (216) of the bracket (70), and the upright support members (222A-H) are provided with holes at the open top (212) of the bracket (70). The ventilated top plates (226) of (228A-F) are coupled together, and the holes (228A-F) are in communication with the device receiving areas (224A-C) through which heated air can exit the device receiving area (224A-C). To the first plenum (90A) or the second plenum (90B) positioned above the vented ceiling, the erect support members (222A-H) are along the front (214) of the bracket (70) at the open bottom (210) Coupled together by the front rail (230) along the rear (216) of the bracket (70) at the open bottom (210) by the rear rail (232) along the bracket (70) The four upright support members (222A-D) aligned with the front portion (214) can be coupled by any desired number of front and rear extension members (236) to four upright support members aligned along the rear portion (216) of the bracket (70). (222E-H), member (236) is capable of providing structural stability to bracket (70), two openings (240E) and (240F) each housing a rectifier (242), four openings (240A-D) each Each of them houses a network switching device (244), the rectifier (242) can be configured to rectify from about (480V) to about (48V), and the electrical socket (132) coupled to the first power distribution panel (120A) can be connected to one of them. A rectifier (242), an electrical outlet (132) coupled to the second power distribution panel (120B) can be coupled to other rectifiers in the rectifier (242), each rectifier (242) receiving a first power distribution from a different power distribution panel The power of the panel (120A) or the second power distribution panel (120B), the device receiving areas (224A to C) can each be divided into four sections "S1 to S4". The device receiving areas (224A to C) are not limited. Combined with a blade server with a specific number of Ethernet ports, the device receiving area (224A-C) is not limited to combining with an Ethernet port. The blade server is capable of being used in conjunction with a blade server having other types of communication ports, each having a plurality of air moving devices (264) oriented to blow air upward through the device Receiving areas (224A-C), these air moving components (260) are mounted between the upright support members (222A-H) of the bracket (70), each air moving assembly (260) including a frame (262), The frame is configured to be mounted in one of the device receiving areas (224A-C), the frame (262) housing a plurality of air moving devices (264), each air moving device being oriented such that air flows in substantially the same upward direction The bracket (70) includes nine air moving assemblies (260), the number of air moving components mounted within each of the equipment receiving areas (224A-C) being capable of being based, at least in part, on cooling the computing equipment received therein The amount of air circulation determines that the air moving components (260) each receive power from the electrical conductors (130) that carry power to the cradle (70) to energize the computing device (102) contained therein, erecting the equipment The zones (224A-C) can be customized to receive a predetermined set of computing devices, and the upright device receiving zones (224A-C) can be configured to receive the blade server (103) in a vertical orientation, the standard 19" rack mounted computer gear capable Installed inside the erecting equipment receiving area (224A-C), the fan in the rack-mounted computer gear draws air from the central corridor (72) inside the cabinet (12) to the erecting equipment receiving area (224A~) In C), the air will pass through the rack mount computer gear, thereby being heated away from the rack mounted computer gear adjacent the rear (216) of the bracket (70), and the heated air can exit the bracket ( 70) mounting the computer gear, air inside or between the rear portion (216) of the bracket (70) and the adjacent one of the first longitudinal side portion (14) and the second longitudinal side portion (16) The moving assembly (260) heats the inside of the bracket (70) The air is directed upward toward the open top (212) of the bracket (70), and the air moving assembly (260) will assist in drawing heated air out of the bracket (70) and into the erecting device receiving area (224A~) C), in these upright device receiving areas, the air moving assembly (260) directs the heated air upward toward the open top (212) of the bracket (70), and the rack mounted computer gear can be mounted to the upright device in any orientation. In the area (224A-C), the rack mounted computer gears can be mounted into the erect equipment receiving areas (224A-C) in a manner similar to a blade server, and an alternative embodiment of the cradle (70) can be used, where The rack mounting computer gear can be mounted to extend longitudinally within the housing (12), and the isolating coupling 86 can be coupled to the upright support members (222A-H) along the bottom (210) of the bracket (70), the isolating coupling (86) It is also possible to couple one or more of the upright support members (222E-H) to the first longitudinal side (14) and the second longitudinal side (16) of the tank (12), a first vertical cooling system ( 100A) cooling upward through the bracket (70) disposed along the first longitudinal side (14) Gas, while the second vertical cooling system (100B) cools the air flowing upward through the bracket (70) disposed along the second longitudinal side (16), the second vertical cooling system (100B) and the first vertical cooling The system (100A) is substantially identical, the second vertical cooling system (100B) comprising two fluid streams, a refrigerant stream, a cold water or a cooling water stream, in the second vertical cooling system (100B), the refrigerant stream passes through its heat Passed to the cooling water stream to be cooled, the second vertical cooling system (100B) includes a water/refrigerant heat exchanger (300) configured to transfer heat from the refrigerant stream to the cooling water stream, the cooling water stream is received From an externally cooled water supply or water source (310) that is a continuous cooling water stream, the cooling water stream can reside in a closed loop (312) that returns heated prior cooling water to an external cooling water source (310) for re-cooling The closed loop (312) and the water/refrigerant heat exchanger (300) are spaced apart from the carrier (70), the refrigerant is brought to the carrier, the closed circuit (312) of the cooling water flow, and the water/refrigerant heat exchange (300) is isolated from the computing device (102) of the data center (10), cooling water The flow is transported by the first water line (318) to the tank (12) and the second water line (320) is transported away from the tank (12), the tank (12) comprising a T-shaped inlet valve (330), the T-shaped inlet The valve directs a portion of the flow of cooling water received from the first water line (318) to a first vertical cooling system (100A) and a second vertical cooling system (100B), the tank (12) including a T-shaped outlet valve (332) The T-shaped outlet valve will direct the flow of cooling water received by the first vertical cooling system (100A) and the second vertical cooling system (100B) to the second water line (320), the inlet tube (334) Between an outlet of the inlet valve (330) and a water/refrigerant heat exchanger (300) of the second vertical cooling system (100B), the inlet tube (334) carries a portion of the cooling water stream to the water/cooling a heat exchanger (300), a similar inlet tube is coupled between the other outlet of the inlet valve (330) and the water/refrigerant heat exchanger (300) of the first vertical cooling system (100A), the outlet tube (336) is coupled between the water/refrigerant heat exchanger (300) of the second vertical cooling system (100B) and an inlet of the outlet valve (332), and the outlet pipe (336) streams the cooling water from the water/cooling Hot agent The vessel (300) is transported to an outlet valve (332), and a similar outlet pipe is coupled to the water/refrigerant heat exchanger (300) of the first vertical cooling system (100A) and the other inlet of the outlet valve (332). The inlet tube (334) and the water tray (340) together form a passive dehumidification system (350) that limits the humidity within the tank (12) without consuming more than the first vertical cooling system ( 100A) and any additional electrical power consumed by the second vertical cooling system (100B), in the second vertical cooling system (100B), the coolant flow through the closed loop (352), the closed loop (352) including the refrigerant A supply manifold (354) and a refrigerant return manifold (356), the refrigerant supply manifold (354) carries the cooled refrigerant to a plurality of supply tubes (360), each of which is connected to a plurality of refrigeration units One of the agent/air heat exchangers (370), two heat exchangers (370) are provided for each bracket (70), and a plurality of return tubes (372) are each coupled to a plurality of heat exchangers (370) One of a plurality of return tubes (372) transports the heated refrigerant from the plurality of heat exchangers (370) to the refrigerant return manifold (356), including two for each bracket (70) Heat exchangers (370), a plurality of supply tubes (360) and a plurality of return tubes (372) each comprising ten conduits, the refrigerant return manifold (356) being received from the heat exchanger (370) The heated refrigerant is transported back to the water/refrigerant heat exchanger (300) for re-cooling by the cooling water flow in the water/refrigerant heat exchanger (300), the refrigerant supply manifold (354), and the supply pipe ( 360), the refrigerant return manifold (356) and the return conduit (372) can each include one or more flow regulators or valves (358) configured to control or limit the flow of refrigerant therethrough, refrigerant supply variance The tube (354) includes a valve (358) prior to the first supply tube (360) that regulates the flow of refrigerant into the supply tube (360), each of which includes a valve (358) The valve (358) regulates the flow of refrigerant to each heat exchanger (370), and by selectively adjusting the flow of refrigerant through the valve (358), the amount of cooling supplied to each heat exchanger (370) can Adjusted, the second vertical cooling system (100B) can include a coupling to the refrigerant supply manifold (354), the supply tube (360), the refrigerant return manifold (356), and/or the return conduit (372) Or a plurality of sensors (376), each of which can be used to monitor a temperature-generating temperature signal of the refrigerant flow, the second vertical cooling system (100B) can include a cooling system controller (380), the cooling The system controller can be coupled to an inlet valve (330) and a temperature sensor (376), each heat exchanger (370) having a coil assembly (373) from which refrigerant flows from the supply tube (360) (370) circulates through its coil assembly (373), the air above the bracket (70) is hot because it has been heated by the computing device (102) and the heated air travels up through the heat exchanger (370) Cooled by the refrigerant, each heat exchanger (370) is implemented as a radiator type evaporator, the coil assembly (373) of the heat exchanger is opposite the front (214) and open top of the bracket (70) ( 212) disposed at an angle, the coil assembly (373) has one or more cooling surfaces at which air outside the coil assembly (373) and refrigerant flowing within the coil assembly (373) The heat exchange between the heat exchanger (370) coil unit (373) can be angled to maximize the available The number of cooling surfaces of the space of the heat exchanger, thereby providing a maximum amount of cooling capacity, defined by the internal angle "A" between the front portion (214) of the bracket (70) and the coil assembly (373) From about 144 degrees to about 158 degrees, an angle from about (144) degrees to about (158) degrees can be defined between the coil assembly (373) and the open top (212) of the bracket (70), An elbow or curved conduit (390) can be coupled between each heat exchanger (370) and at least a portion of the open top (212) of an adjacent bracket (70) to lift from the bracket (70) The heated air is directed into a heat exchanger (370), a curved conduit (390) being coupled to a portion of the individual heat exchanger (370) and the open top (212) of the adjacent bracket (70), each The curved conduits (390) each have a bend (392) defining a curved travel path for the heated air to be driven out of the carrier (70) into the heat exchanger (370), through which the slave (70) will be The raised heated air is directed along the canopy (30) of the casing (12), and the curved portion (392) helps prevent along the upper first plenum (90A) and the second plenum (90B) The canopy (30) forms the back The back pressure pushes the heated air back into the open top (212) of the bracket (70), the curved conduit (390) including an internal baffle (394) that bends the curved conduit (390) The travel path branches, the sealing member (396) is positioned between the rear portion (216) of the bracket (70) and the first longitudinal side portion (14) and the second longitudinal side portion (16), and the sealing member (397) is positioned Between the front portion (214) of the bracket (70) and the heat exchanger (370), each bracket (70) includes an air moving device (264) that is consumed by the air moving device (264) to be sufficiently cooled The amount of power of the computing device (102) can be determined, at least in part, by how air flows from the carrier (70) into the heat exchanger (370), the curved conduit (390) being in the upper first plenum (90A) and The shape in the two plenums (90B) is determined by the amount of power consumed by the air moving device (264), which can be configured to minimize the amount of power consumed by the air moving device (264), the cabinet (12) Positioning the air outside the container with an environment suitable for cooling the temperature of the computing device (102) mounted within the cradle (70), then the container can include such an opening Air from the external environment can flow into the container through the opening to cool the computing device (102), the container can also include an opening through which air heated by the computing device (102) can exit the container Entering into the external environment, the amount of power consumed by the air moving device (264) to cool the computing device (102) can be determined, at least in part, by how air flows from the carrier (70) into the heat exchanger (370). The power of the air moving device (264) to cool the computing device (102) is determined by the amount of air flowing from the carrier (70) into the heat exchanger (370).

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