CN211579693U - Combined power supply and distribution system of IDC machine room building - Google Patents

Combined power supply and distribution system of IDC machine room building Download PDF

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Publication number
CN211579693U
CN211579693U CN202020567435.5U CN202020567435U CN211579693U CN 211579693 U CN211579693 U CN 211579693U CN 202020567435 U CN202020567435 U CN 202020567435U CN 211579693 U CN211579693 U CN 211579693U
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distribution
control module
module
power
building
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陈银亮
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Henan Branch Electrical Electrical Automation Co ltd
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Henan Branch Electrical Electrical Automation Co ltd
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    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B70/00Technologies for an efficient end-user side electric power management and consumption
    • Y02B70/30Systems integrating technologies related to power network operation and communication or information technologies for improving the carbon footprint of the management of residential or tertiary loads, i.e. smart grids as climate change mitigation technology in the buildings sector, including also the last stages of power distribution and the control, monitoring or operating management systems at local level
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B90/00Enabling technologies or technologies with a potential or indirect contribution to GHG emissions mitigation
    • Y02B90/20Smart grids as enabling technology in buildings sector
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y04INFORMATION OR COMMUNICATION TECHNOLOGIES HAVING AN IMPACT ON OTHER TECHNOLOGY AREAS
    • Y04SSYSTEMS INTEGRATING TECHNOLOGIES RELATED TO POWER NETWORK OPERATION, COMMUNICATION OR INFORMATION TECHNOLOGIES FOR IMPROVING THE ELECTRICAL POWER GENERATION, TRANSMISSION, DISTRIBUTION, MANAGEMENT OR USAGE, i.e. SMART GRIDS
    • Y04S20/00Management or operation of end-user stationary applications or the last stages of power distribution; Controlling, monitoring or operating thereof
    • Y04S20/12Energy storage units, uninterruptible power supply [UPS] systems or standby or emergency generators, e.g. in the last power distribution stages
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y04INFORMATION OR COMMUNICATION TECHNOLOGIES HAVING AN IMPACT ON OTHER TECHNOLOGY AREAS
    • Y04SSYSTEMS INTEGRATING TECHNOLOGIES RELATED TO POWER NETWORK OPERATION, COMMUNICATION OR INFORMATION TECHNOLOGIES FOR IMPROVING THE ELECTRICAL POWER GENERATION, TRANSMISSION, DISTRIBUTION, MANAGEMENT OR USAGE, i.e. SMART GRIDS
    • Y04S20/00Management or operation of end-user stationary applications or the last stages of power distribution; Controlling, monitoring or operating thereof
    • Y04S20/20End-user application control systems
    • Y04S20/248UPS systems or standby or emergency generators

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Abstract

The utility model relates to a power supply technical field, concretely relates to IDC computer lab building combination formula supplies power distribution system, join in marriage the motor room building including DC1, DC2 joins in marriage the motor room building, DC3 joins in marriage the motor room building and DC4 joins in marriage the motor room building, DC1 joins in marriage the upstairs and is equipped with DC1 distribution generating set of motor room, DC1 distribution generating set and DC1 join in marriage motor room building electric connection, DC2 joins in marriage and is equipped with DC2 distribution generating set upstairs, DC2 distribution generating set and DC2 join in marriage motor room building electric connection, DC3 joins in marriage and is equipped with DC3 distribution generating set on the motor room building, DC3 distribution generating set and DC3 join in marriage motor room building electric connection, DC1 distribution generating set, DC2 distribution generating set and DC3 distribution generating set respectively with DC4 motor room building electric connection. The utility model provides a stability is strong, safe and reliable, and effectual utilization generating set provides electric power, reduces investment and wasting of resources, and convenient operation's IDC computer lab building combination formula supplies distribution system for overcome defect among the prior art.

Description

Combined power supply and distribution system of IDC machine room building
Technical Field
The utility model relates to a power supply technical field, concretely relates to IDC computer lab building combination formula power supply and distribution system.
Background
An IDC (Internet Data Center) machine room is a machine room environment of a telecommunication professional level established by a telecommunication department by utilizing the existing Internet communication lines and bandwidth resources, and can provide all-round services in the aspects of server hosting, renting, related value adding and the like for enterprises and governments.
At present, for a large-scale IDC machine room, when the commercial power fails, in order to not affect the normal use of a server, a generator set is usually used for carrying out emergency power supply for the IDC machine room, so that the server can maintain normal work and protect the software and hardware of the server from being damaged; in order to ensure the normal power supply stability of the IDC machine room, two sets of power distribution equipment are generally required to be purchased for power supply, namely, a means for improving the reliability of the system by using a parallel model of the system by using a redundancy technology; however, for a plurality of IDC machine rooms, each IDC machine room uses two sets of power distribution equipment for power supply, which often increases the cost of a power supply and distribution system and causes resource waste, and a redundancy technology is not adopted, so that the power supply stability of the IDC machine rooms is often reduced, and the server is powered off, thereby affecting the normal use of the server, and even causing the damage to the software and hardware of the server.
Therefore, the IDC machine room and building combined power supply and distribution system which is strong in stability, safe and reliable, capable of effectively utilizing the generator set to provide power, capable of reducing investment and resource waste and convenient to operate is produced, and has a wide market prospect.
Disclosure of Invention
Not enough to prior art, the utility model provides a stability is strong, safe and reliable, and effectual utilization generating set provides electric power, reduces investment and wasting of resources, and convenient operation's IDC computer lab building combination formula supplies distribution system for overcome defect among the prior art.
The utility model adopts the technical proposal that: the utility model provides an IDC computer lab building combination formula power supply and distribution system, including DC1 distribution machine room building, DC2 distribution machine room building, DC3 distribution machine room building and DC4 distribution machine room building, DC1 is joined in marriage the upstairs and is equipped with DC1 distribution generating set of computer lab, DC1 distribution generating set and DC1 distribution machine room building electric connection, DC2 is joined in marriage the upstairs and is equipped with DC2 distribution generating set of computer lab, DC2 distribution generating set and DC2 distribution machine room building electric connection, DC3 is joined in marriage the upstairs and is equipped with DC3 distribution generating set of computer lab, DC3 distribution generating set and DC3 distribution machine room building electric connection, DC1 distribution generating set, DC2 distribution generating set and DC3 distribution generating set join in marriage the electricity of computer lab electric connection with DC4 respectively.
DC1 power distribution room include G1 distribution module and G2 distribution module, G1 distribution module and G2 distribution module respectively with DC1 distribution generating set electric connection, DC2 power distribution room includes G3 distribution module and G4 distribution module, G3 distribution module and G4 distribution module respectively with DC2 distribution generating set electric connection, DC3 distribution room includes G5 distribution module and G6 distribution module, G5 distribution module and G6 distribution module respectively with DC3 distribution generating set electric connection, DC4 power distribution room includes G7 distribution module and G8 distribution module, G7 distribution module and G8 distribution module respectively with DC1 distribution generating set, DC2 distribution generating set and DC3 distribution generating set electric connection.
DC1 join in marriage and be equipped with PC1 control module on the electrical room building, be equipped with PC2 control module on the electrical room building is joined in marriage to DC2, be equipped with PC3 control module on the electrical room building is joined in marriage to DC3, be equipped with PC4 control module, PC5 control module and PC6 control module on the electrical room building is joined in marriage to DC4, PC4 control module and PC1 control module be connected with DC1 distribution electricity generation group communication respectively, PC5 control module and PC2 control module are connected with DC2 distribution electricity generation group communication respectively, PC6 control module and PC3 control module are connected with DC3 distribution electricity generation group communication respectively.
A first Ethernet alternating current module and a second Ethernet alternating current module are arranged outside the DC1 power distribution room, and the first Ethernet alternating current module and the second Ethernet alternating current module are respectively in communication connection with a PC1 control module, a PC2 control module, a PC3 control module, a PC4 control module, a PC5 control module and a PC6 control module.
PC1 control module, PC2 control module, PC3 control module, PC4 control module, PC5 control module and PC6 control module all include two control CPU, two communication interface, two independent power supplies, PLC control mainboard and IO monitoring module, two control CPU, two communication interface and this IO monitoring module buckle respectively and install on PLC control mainboard, two control CPU, two communication interface and this IO monitoring module respectively with this PLC control mainboard electric connection, two independent power supplies respectively with two control CPU electric connection, the feeder ear buckle of two independent power supplies is fixed at this PLC control mainboard, two communication interface respectively with first ethernet interchange module and second ethernet interchange module communication connection.
A DC1 power supply control module is fixedly fastened on the DC1 power distribution generator set, a DC1 power distribution generator set is respectively and electrically connected with a DC1 power distribution machine room building and a DC4 power distribution machine room building through the DC1 power supply control module, a DC2 power supply control module is fixedly fastened on the DC2 power distribution generator set, the DC2 power distribution generator set is respectively and electrically connected with a DC2 power distribution machine room building and a DC4 power distribution machine room building through a DC2 power supply control module, a DC3 power supply control module is fixedly fastened on the DC3 power distribution generator set, and the DC3 power distribution generator set is respectively and electrically connected with a DC3 power distribution machine room building and a DC4 power distribution machine room building through a DC3 power supply control module; the control system is characterized in that the PC1 control module and the PC4 control module are respectively in communication connection with the DC1 power supply control module, the PC2 control module and the PC5 control module are respectively in communication connection with the DC2 power supply control module, and the PC3 control module and the PC6 control module are respectively in communication connection with the DC3 power supply control module.
The utility model has the advantages that: firstly, the utility model discloses a DC1 distribution power generation room, DC2 distribution power generation room, DC3 distribution power generation room and DC4 distribution power generation room, DC1 distribution power generation room is last to be equipped with DC1 distribution generating set, DC1 distribution generating set and DC1 distribution power generation room electric connection, C2 distribution power generation room is last to be equipped with DC2 distribution generating set, DC2 distribution generating set and DC2 distribution power generation room electric connection, C3 distribution power generation room is last to be equipped with DC3 distribution generating set, DC3 distribution generating set and DC3 distribution power generation room electric connection, DC1 distribution generating set, DC2 distribution generating set and DC3 distribution generating set respectively with DC4 distribution power generation room electric connection, the utility model discloses a DC1 distribution generating set, DC2 distribution generating set and DC3 distribution generating set carry out the effectual combination to supply power for DC1 distribution power generation room, DC2 distribution power generation room, DC3 distribution power generation room and DC4 distribution power generation room, thereby reducing the waste of investment and resources and effectively utilizing the generator set to provide electric power; secondly, the utility model discloses a PC1 control module, PC2 control module, PC3 control module, PC4 control module, PC5 control module and PC6 control module that are equipped with control DC1 distribution generating set, DC2 distribution generating set and DC3 distribution generator join in marriage the power supply, thereby be convenient for operate, and make it satisfy the technical requirement of redundant technique, thereby the stability of system has been strengthened, ensure to join in marriage the security of power supply system; thirdly, the utility model discloses a be equipped with DC1 power supply control module, DC2 power supply control module and DC3 power supply control module and distribute electric power to improve the distribution efficiency of electric power, make distribution machine room building can the efficient use electric power, make the utility model discloses fine society and economic benefits have, are the product of easily using widely.
Drawings
Fig. 1 is a schematic diagram of power supply and distribution of the present invention.
Fig. 2 is a schematic diagram of the communication between the control module and the ethernet network according to the present invention.
Detailed Description
As shown in fig. 1 and 2, an IDC machine room building combined power supply and distribution system includes a DC1 power distribution machine room building 1, a DC2 power distribution machine room building 2, a DC3 power distribution machine room building 3, and a DC4 power distribution machine room building 4, a DC1 power distribution generator set 14 is disposed on the DC1 power distribution machine room building 1, the DC1 power distribution generator set 14 is electrically connected to the DC1 power distribution machine room building 1, a DC2 power distribution generator set 24 is disposed on the DC2 power distribution machine room building 2, the DC2 power distribution generator set 24 is electrically connected to the DC2 power distribution machine room building 2, a DC3 power distribution generator set 34 is disposed on the DC3 power distribution machine room building 3, the DC3 power distribution generator set 34 is electrically connected to the DC3 power distribution machine room building 3, and the DC1 power distribution generator set 14, the DC2 power distribution generator set 24, and the DC3 power distribution generator set 34 are electrically connected to.
The DC1 power distribution room building 1 comprises a G1 power distribution module 11 and a G2 power distribution module 12, the G1 power distribution module 11 and the G2 power distribution module 12 are respectively electrically connected with a DC1 power distribution generator set 14, the G1 power distribution module 11 and the G2 power distribution module 12 distribute power generated by the DC1 power distribution generator set 14 to a utility power grid in a first area, the DC 28 power distribution room building 2 comprises a G9 power distribution module 21 and a G4 power distribution module 22, the G3 power distribution module 21 and the G4 power distribution module 22 are respectively electrically connected with a DC2 power distribution generator set 24, the G3 power distribution module 21 and the G4 power distribution module 22 distribute power generated by the DC2 power distribution generator set 24 to a utility power grid in a second area, the DC3 power distribution room building 3 comprises a G3 power distribution module 31 and a G3 power distribution module 32, the G3 power distribution module 31 and the G3 power distribution module 32 generate power in a third area, the G3 power distribution module 31 and the G3 distribution module 3 generate power distribution module In the middle, the DC4 power distribution building 4 includes a G7 power distribution module 41 and a G8 power distribution module 42, the G7 power distribution module 41 and the G8 power distribution module 42 are electrically connected to the DC1 power distribution generator set 14, the DC2 power distribution generator set 24 and the DC3 power distribution generator set 34, respectively, and the power generated by the DC1 power distribution generator set 14, the DC2 power distribution generator set 24 and the DC3 power distribution generator set 34 is distributed to the utility power grid in the fourth area through the G7 power distribution module 41 and the G8 power distribution module 42.
The power distribution room building 1 of the DC1 is provided with a PC1 control module 13, the power distribution room building 2 of the DC2 is provided with a PC2 control module 23, the power distribution room building 3 of the DC3 is provided with a PC3 control module 33, the power distribution room building 4 of the DC4 is provided with a PC4 control module 43, a PC5 control module 44 and a PC6 control module 45, the PC4 control module 43 and the PC1 control module 13 are respectively connected with the DC1 distribution power generation set 14 in a communication way, so that the DC1 power distribution unit 14 is turned on or off via the PC4 control module 43 and the PC1 control module 13, the PC5 control module 44 and the PC2 control module 23 are respectively in communication with the DC2 power distribution unit 24, so that the DC2 power distribution group 24 is turned on or off by the PC5 control module 44 and the PC2 control module 23, the PC6 control module 45 and the PC3 control module 33 are respectively in communication with the DC3 power distribution group 34, the DC3 power distribution stack 34 is thus turned on or off by the PC6 control module 45 and the PC3 control module 23.
DC1 joins in marriage and is equipped with first ethernet and exchange module 61 and second ethernet and exchange module 62 outside the motor building 1, first ethernet exchange module 61 and second ethernet exchange module 62 respectively with PC1 control module 13, PC2 control module 23, PC3 control module 33, PC4 control module 43, PC5 control module 44 and PC6 control module 45 communication connection, PC1 control module 13, PC2 control module 23, PC3 control module 33, PC4 control module 43, PC5 control module 44 and PC6 control module 45 communication connection communicate with the ethernet through first ethernet exchange module 61 and second ethernet exchange module 62 respectively, realize the utility model discloses two network communication, thereby ensure the utility model discloses can accept commercial power normal or outage signal fast.
The PC1 control module 13, the PC2 control module 23, the PC3 control module 33, the PC4 control module 43, the PC5 control module 44 and the PC6 control module 45 respectively comprise two control CPUs, two communication interfaces, two independent power supplies, a PLC control mainboard and an IO monitoring module, the two control CPUs, the two communication interfaces and the IO monitoring module are respectively installed on the PLC control mainboard in a buckling mode, the two control CPUs, the two communication interfaces and the IO monitoring module are respectively and electrically connected with the PLC control mainboard, the two independent power supplies are respectively and electrically connected with the two control CPUs, power supply ends of the two independent power supplies are fixedly buckled on the PLC control mainboard, the two communication interfaces are respectively and communicatively connected with the first Ethernet alternating current module 61 and the second Ethernet alternating current module 62, so that communication with the Ethernet is convenient, and the PC1 control module 13, the PC2 control module 23 and the PC3 control module 33, The PC4 control module 43, the PC5 control module 44 and the PC6 control module 45 all adopt an S7-1500 redundancy system, so that the configuration design meets the high reliability requirements of equipment and the system according to the redundancy technology of a rack, a power supply, a CPU and a communication bus, namely, two control CPUs in the S7-1500 are respectively provided with an independent power supply module, the two independent control CPUs are used for logic operation and processing and realizing the online thermal redundancy technology between the CPUs, the IO monitoring module carries out distributed I/O monitoring on an access signal and an output signal and is used for acquiring signals of the module and finishing the corresponding monitoring or control function, and therefore, each set of control module is a double-click thermal redundancy system with the CPUs, the power supply and the network.
A DC1 power supply control module 15 is fixed on the DC1 power distribution generating set 14 in a clamping manner, the DC1 power distribution generating set 14 is electrically connected with a DC1 power distribution building 1 and a DC4 power distribution building 4 respectively through the DC1 power supply control module 15, the DC1 power distribution generating set 14 is controlled by the DC1 power supply control module 15 to transmit the generated power to the power distribution building 1 or the DC4 power distribution building 4, a DC2 power supply control module 25 is fixed on the DC2 power distribution generating set 24 in a clamping manner, the DC2 power distribution generating set 24 is electrically connected with the DC2 power distribution building 2 and the DC4 power distribution building 4 respectively through the DC2 power supply control module 25, the DC2 power distribution generating set 24 is controlled by the DC2 power supply control module 25 to transmit the generated power to the power distribution building 2 or the DC4 power distribution building 4, a DC3 power supply control module 26 is fixed on the DC3 power distribution generating set 34 in a clamping manner, and the DC3 power distribution generating set 34 is electrically connected with the DC 7373 power distribution building 4 and the power distribution building 863, the DC2 power distribution generator set 34 controls the generated power to be transmitted to the power distribution building 4 or the DC4 power distribution building 4 through the DC2 power supply control module 35; the PC1 control module 13 and the PC4 control module 43 are respectively in communication connection with the DC1 power supply control module 15, the PC2 control module 23 and the PC5 control module 44 are respectively in communication connection with the DC2 power supply control module 25, and the PC3 control module 33 and the PC6 control module 45 are respectively in communication connection with the DC3 power supply control module 35, so that the control modules can control the transmission of power conveniently.
When the utility grid where the DC1 power distribution building 1 is located has a power failure, first, the first ethernet alternating-current module 61 and the second ethernet alternating-current module 62 receive a power failure signal from the ethernet and transmit the information to the PC1 control module 13 and the PC4 control module 43; then, the PC1 control module 13 and the PC4 control module 43 control the DC1 power distribution generator set 14 to generate power, and at the same time, the PC1 control module 13 and the PC4 control module 43 control the DC1 control module 15 to supply power to the DC1 power distribution building 1; when the utility grid in which the DC2 power distribution building 2 or the DC3 power distribution building 3 is located has a power failure, the DC2 control module 25 or the DC3 control module 35 is used to supply power to the DC2 power distribution building 2 or the DC3 power distribution building 3, as described above.
When the utility grid where the DC4 power distribution building 4 is located has a power failure, first, the first ethernet ac module 61 and the second ethernet ac module 62 receive a power failure signal from the ethernet and transmit the information to the PC1 control module 13, the PC2 control module 23, the PC3 control module 33, the PC4 control module 43, the PC5 control module 44, and the PC6 control module 45; then, the PC1 control module 13 and the PC4 control module 43 control part of the motors of the DC1 distribution generator set 14 to generate power, and at the same time, the PC1 control module 13 and the PC4 control module 43 control the DC1 control module 15 to supply power to the DC4 distribution building 4, and similarly, the PC2 distribution generator set 24 and the DC2 distribution generator set 24 control part of the motors to generate power and supply power to the DC4 distribution building 4.
When the utility power grid in which the DC1 power distribution room building 1, the DC2 power distribution room building 2, the DC3 power distribution room building 3 and the DC4 power distribution room building 4 are located has a power failure, first, the first ethernet alternating-current module 61 and the second ethernet alternating-current module 62 receive a power failure signal from the ethernet and transmit the information to the PC1 control module 13, the PC2 control module 23, the PC3 control module 33, the PC4 control module 43, the PC5 control module 44 and the PC6 control module 45; then, the PC1 control module 13, the PC2 control module 23, the PC3 control module 33, the PC4 control module 43, the PC5 control module 44, and the PC6 control module 45 respectively control the DC1 distribution generator set 14, the DC2 distribution generator set 24, and the DC3 distribution generator set 34 to generate power, and simultaneously, the DC1 control module 15, the DC2 control module 25, and the DC3 control module 35 are controlled to distribute power to the DC1 distribution building 1, the DC2 distribution building 2, the DC3 distribution building 3, and the DC4 distribution building 4, so as to supply power to the DC1 distribution building 1, the DC2 distribution building 2, the DC3 distribution building 3, and the DC4 distribution building 4.
The utility model discloses a stability is strong, safe and reliable, and effectual utilization generating set provides electric power, reduces investment and wasting of resources, and convenient operation's IDC computer lab building combination formula supplies distribution system, makes the utility model discloses extensive market prospect has.

Claims (6)

1. The utility model provides a IDC computer lab building combination formula power supply and distribution system which characterized in that: distribution of electricity building (1) including DC1, DC2 distribution of electricity building (2), DC3 distribution of electricity building (3) and DC4 distribution of electricity building (4), be equipped with DC1 distribution of electricity generating set (14) on DC1 distribution of electricity building (1), DC1 distribution of electricity generating set (14) and DC1 distribution of electricity building (1) electric connection, be equipped with DC2 distribution of electricity generating set (24) on DC2 distribution of electricity building (2), DC2 distribution of electricity generating set (24) and DC2 distribution of electricity building (2) electric connection, be equipped with DC3 distribution of electricity generating set (34) on DC3 distribution of electricity building (3), DC3 distribution of electricity generating set (34) and DC3 distribution of electricity building (3) electric connection, DC1 distribution of electricity generating set (14), DC2 distribution of electricity generating set (24) and DC3 distribution of electricity generating set (34) respectively with DC4 distribution of electricity building (4) electric connection.
2. The IDC room building combined power supply and distribution system according to claim 1, wherein: the DC1 power distribution building (1) comprises a G1 power distribution module (11) and a G2 power distribution module (12), the G1 power distribution module (11) and the G2 power distribution module (12) are respectively electrically connected with a DC1 power distribution generator set (14), the DC2 power distribution building (2) comprises a G3 power distribution module (21) and a G4 power distribution module (22), the G3 power distribution module (21) and the G4 power distribution module (22) are respectively electrically connected with a DC2 power distribution generator set (24), the DC3 power distribution building (3) comprises a G5 power distribution module (31) and a G6 power distribution module (32), the G5 power distribution module (31) and the G6 power distribution module (32) are respectively electrically connected with a DC3 power distribution generator set (34), the DC4 power distribution building (4) comprises a G7 power distribution module (41) and a G8 power distribution module (42), the G7 power distribution module (41) and the G8 power distribution module (42) are electrically connected with the DC1 power distribution generator set (14), the DC2 power distribution generator set (24) and the DC3 power distribution generator set (34) respectively.
3. The IDC room building combined power supply and distribution system according to claim 1, wherein: DC1 join in marriage and be equipped with PC1 control module (13) on power generation machine room building (1), be equipped with PC2 control module (23) on DC2 joins in marriage the power generation machine room building (2), be equipped with PC3 control module (33) on DC3 joins in marriage power generation machine room building (3), be equipped with PC4 control module (43) on DC4 joins in marriage power generation machine room building (4), PC5 control module (44) and PC6 control module (45), PC4 control module (43) and PC1 control module (13) be connected with DC1 distribution electricity generation group (14) communication respectively, PC5 control module (44) and PC2 control module (23) are connected with DC2 distribution electricity generation group (24) communication respectively, PC6 control module (45) and PC3 control module (33) are connected with DC3 electricity generation group (34) communication respectively.
4. The IDC room-building combined power supply and distribution system of claim 3, wherein: the DC1 power distribution machine room building (1) is externally provided with a first Ethernet alternating current module (61) and a second Ethernet alternating current module (62), and the first Ethernet alternating current module (61) and the second Ethernet alternating current module (62) are respectively in communication connection with a PC1 control module (13), a PC2 control module (23), a PC3 control module (33), a PC4 control module (43), a PC5 control module (44) and a PC6 control module (45).
5. The IDC room-building combined power supply and distribution system of claim 4, wherein: PC1 control module (13), PC2 control module (23), PC3 control module (33), PC4 control module (43), PC5 control module (44) and PC6 control module (45) all include two control CPU, two communication interfaces, two independent power supplies, PLC control mainboard and IO monitoring module, two control CPU, two communication interfaces and this IO monitoring module buckle respectively and install on PLC control mainboard, two control CPU, two communication interfaces and this IO monitoring module respectively with this PLC control mainboard electric connection, two independent power supplies respectively with two control CPU electric connection, the feed end buckle of two independent power supplies is fixed at this PLC control mainboard, two communication interfaces respectively with first ethernet AC module (61) and second ethernet AC module (62) communication connection.
6. The IDC room-building combined power supply and distribution system of claim 3, wherein: a DC1 power supply control module (15) is fixedly fastened on the DC1 power distribution generator set (14) in a buckling manner, the DC1 power distribution generator set (14) is respectively electrically connected with a DC1 power distribution machine room building (1) and a DC4 power distribution machine room building (4) through the DC1 power supply control module (15), a DC2 power supply control module (25) is fixedly fastened on the DC2 power distribution generator set (24), the DC2 power distribution generator set (24) is respectively electrically connected with a DC2 power distribution machine room building (2) and a DC4 power distribution machine room building (4) through the DC2 power supply control module (25), a DC3 power supply control module (26) is fixedly fastened on the DC3 power distribution generator set (34), and the DC3 power distribution generator set (34) is respectively electrically connected with a DC3 power distribution machine room (3) and a DC4 power distribution machine room building (4) through the DC3 power supply control module (35); the PC1 control module (13) and the PC4 control module (43) are respectively in communication connection with the DC1 power supply control module (15), the PC2 control module (23) and the PC5 control module (44) are respectively in communication connection with the DC2 power supply control module (25), and the PC3 control module (33) and the PC6 control module (45) are respectively in communication connection with the DC3 power supply control module (35).
CN202020567435.5U 2020-04-16 2020-04-16 Combined power supply and distribution system of IDC machine room building Active CN211579693U (en)

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CN202020567435.5U CN211579693U (en) 2020-04-16 2020-04-16 Combined power supply and distribution system of IDC machine room building

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Application Number Priority Date Filing Date Title
CN202020567435.5U CN211579693U (en) 2020-04-16 2020-04-16 Combined power supply and distribution system of IDC machine room building

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CN211579693U true CN211579693U (en) 2020-09-25

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