CN203012499U - Cooling heating and power control system based on IDC data center - Google Patents
Cooling heating and power control system based on IDC data center Download PDFInfo
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- CN203012499U CN203012499U CN2013200423986U CN201320042398U CN203012499U CN 203012499 U CN203012499 U CN 203012499U CN 2013200423986 U CN2013200423986 U CN 2013200423986U CN 201320042398 U CN201320042398 U CN 201320042398U CN 203012499 U CN203012499 U CN 203012499U
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- Y—GENERAL 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
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
- Y02P90/00—Enabling technologies with a potential contribution to greenhouse gas [GHG] emissions mitigation
- Y02P90/02—Total factory control, e.g. smart factories, flexible manufacturing systems [FMS] or integrated manufacturing systems [IMS]
Abstract
The utility model provides a cooling heating and power control system based on an IDC data center and relates to a cooling heating and power control system. The utility model aims to solve problems of uncontrollable refrigerating capacity, heat energy waste, low energy utilization rate, large power grid load and environment pollution of a prior system. According to the utility model, electric energy signals, monitoring signals and heat energy signals of a combustion engine generator set of the cooling heating and power control system based on the IDC data center are transmitted to an electric energy detecting device, a monitoring circuit and a heat energy distributing device respectively. Two electric energy signals of the electric energy detecting device are transmitted to a power grid feedback circuit and an IDC data control center circuit respectively. Monitoring signals of a monitoring circuit are transmitted to an IDC data control center. Monitoring signals of a power grid are transmitted to the monitoring circuit. Electric energy signals of the power grid feedback circuit are transmitted to the power grid. Two heat energy signals of a heat energy distributing device are transmitted to a lithium bromide cooling device and a heat energy outputting device respectively. And two cooling capacity signals of the lithium bromide cooling device are transmitted to the IDC data control center circuit and a cool capacity output device respectively. The cooling heating and power control system based on the IDC data center is used for communication and cooling.
Description
Technical field
The utility model relates to a kind of control system, is specifically related to the cool and thermal power control system based on IDC data center.
Background technology
The electricity consumption of IDC Internet Data Center data center is in MW class, communication apparatus electricity consumption and refrigeration power consumption have accounted for very large proportion, existing cool and thermal power control system exists that refrigerating capacity is not controlled, thermal waste is serious, the energy utilize low, network load large, increased the problem of environmental pollution.
The utility model content
The utility model exists in order to solve existing cool and thermal power control system that refrigerating capacity is not controlled, thermal waste is serious, the utilization factor energy is low, network load large, increased the problem of environmental pollution.
Cool and thermal power control system based on IDC data center comprises oil-electric engine group, electrical network feedback circuit, electrical network, supervisory circuit, heat energy distributor, lithium bromide refrigerating device, electric energy detection device, IDC Data Control Center circuit, cold output unit and heat output unit
Electric energy detection device has two electric power signal output terminals and an electric power signal input end,
The heat energy distributor has two heat energy signal output parts and a heat energy signal input part,
The lithium bromide refrigerating device has two cold signal output parts and a heat energy signal input part,
IDC Data Control Center circuit has electric power signal input end, pilot signal input end and cold signal input part,
The electric power signal output terminal of described oil-electric engine group is connected with the electric power signal input end of electric energy detection device,
The first electric power signal output terminal of electric energy detection device is connected with the electric power signal input end of electrical network feedback circuit,
The second electric power signal output terminal of electric energy detection device is connected with the electric power signal input end of IDC Data Control Center circuit,
The pilot signal output terminal of oil-electric engine group is connected with the oil-electric engine group pilot signal input end of supervisory circuit,
The pilot signal output terminal of supervisory circuit is connected with the pilot signal input end of IDC Data Control Center circuit,
The power system monitor signal input part of supervisory circuit is connected with the electric power signal output terminal of electrical network,
The electric power signal input end of electrical network is connected with the electric power signal output terminal of electrical network feedback circuit,
The heat energy signal output part of oil-electric engine group is connected with the heat energy signal input part of heat energy distributor,
The first heat energy signal output part of heat energy distributor is connected with the heat energy signal input part of lithium bromide refrigerating device,
The second heat energy signal output part of heat energy distributor is connected with the heat energy signal input part of heat output unit,
The first cold signal output part of lithium bromide refrigerating device is connected with the cold signal input part of IDC Data Control Center circuit,
The second cold signal output part of lithium bromide refrigerating device is connected with the cold signal input part of cold output unit.
The utility model improved the energy utilization factor, reduced network load, reduced environmental pollution, the effective execution national energy-saving reduces discharging strategy.Make the waste heat of internal combustion engine can with solving data center's refrigeration problem, make fuel availability more than 80% by the conversion of lithium bromide unit.
Description of drawings
Fig. 1 is the electrical schematic diagram schematic diagram based on the cool and thermal power control system of IDC data center.
Embodiment
Embodiment one, illustrate present embodiment in conjunction with Fig. 1, the described cool and thermal power control system based on IDC data center of present embodiment comprises oil-electric engine group 1, electrical network feedback circuit 2, electrical network 3, supervisory circuit 4, heat energy distributor 5, lithium bromide refrigerating device 6, electric energy detection device 7, IDC Data Control Center circuit 8, cold output unit 9 and heat output unit 10
Electric energy detection device 7 has two electric power signal output terminals and an electric power signal input end,
Lithium bromide refrigerating device 6 has two cold signal output parts and a heat energy signal input part,
IDC Data Control Center circuit 8 total electric power signal input end, pilot signal input end and cold signal input part,
The electric power signal output terminal of described oil-electric engine group 1 is connected with the electric power signal input end of electric energy detection device 7,
The first electric power signal output terminal of electric energy detection device 7 is connected with the electric power signal input end of electrical network feedback circuit 2,
The second electric power signal output terminal of electric energy detection device 7 is connected with the electric power signal input end of IDC Data Control Center circuit 8,
The pilot signal output terminal of oil-electric engine group 1 is connected with the oil-electric engine group pilot signal input end of supervisory circuit 4,
The pilot signal output terminal of supervisory circuit 4 is connected with the pilot signal input end of IDC Data Control Center circuit 8,
The power system monitor signal input part of supervisory circuit 4 is connected with the electric power signal output terminal of electrical network 3,
The electric power signal input end of electrical network 3 is connected with the electric power signal output terminal of electrical network feedback circuit 2,
The heat energy signal output part of oil-electric engine group 1 is connected with the heat energy signal input part of heat energy distributor 5,
The first heat energy signal output part of heat energy distributor 5 is connected with the heat energy signal input part of lithium bromide refrigerating device 6,
The second heat energy signal output part of heat energy distributor 5 is connected with the heat energy signal input part of heat output unit 10,
The first cold signal output part of lithium bromide refrigerating device 6 is connected with the cold signal input part of IDC Data Control Center circuit 8,
The second cold signal output part of lithium bromide refrigerating device 6 is connected with the cold signal input part of cold output unit 9.
The described oil-electric engine group 1 of present embodiment adopts fuel oil or combustion gas unit, the raw material of fuel oil unit adopts diesel oil, combustion gas unit raw material adopts rock gas or biogas, wherein biogas adopts biofermentation, can solve like this resident's the problem of environmental pollutions such as house refuse, human and animal excreta, land for growing field crops stalk;
In order to ensure the work efficiency of internal combustion engine, internal combustion engine is almost operated at full capacity, and the power consumption of data center is regular variation round the clock, therefore detects the power consumption of data center, make corresponding adjustment with the rich back electric quantity of the part electrical network of feeding, reduce local power load;
When environment temperature is low in the winter time, the refrigerating capacity that data center needs reduces with the reduction of temperature, can reduce the working load of lithium bromide refrigerating device 6 under this condition, make more heat change into heat energy, flow near residential block by caliduct, reduce the heating demand of Thermal Corp;
When the summer environment temperature is higher, 6 oeprations at full load of lithium bromide refrigerating device, the generating efficiency of internal combustion unit is below 40%, remaining 60% energy can change into cold, under the refrigeration prerequisite that guarantees data center, unnecessary cold can send low-temperature receiver near to resident by multiplexing caliduct, reduces the power consumption of resident's air-conditioning, reduces the network load in summer;
Detect data center's temperature, outdoor environment temperature, the cold that the predicted data center needs is rationally controlled the refrigeration work load of lithium bromide refrigerating device 6;
The duty of supervisory circuit Real Time Monitoring oil-electric engine group, lithium bromide refrigerating device 6, when having fault to occur, can instantaneous cut-in stand-by power supply, ensure the normal operation of data center;
IDC Data Control Center circuit 8 has realized and national grid, national heat supply network are networked, and the duty of Real Time Monitoring genset, refrigeration unit is carried out the far-end regulation and control.
Claims (1)
1. based on the cool and thermal power control system of IDC data center, it is characterized in that: it comprises oil-electric engine group (1), electrical network feedback circuit (2), electrical network (3), supervisory circuit (4), heat energy distributor (5), lithium bromide refrigerating device (6), electric energy detection device (7), IDC Data Control Center circuit (8), cold output unit (9) and heat output unit (10)
Electric energy detection device (7) has two electric power signal output terminals and an electric power signal input end,
Heat energy distributor (5) has two heat energy signal output parts and a heat energy signal input part,
Lithium bromide refrigerating device (6) has two cold signal output parts and a heat energy signal input part,
IDC Data Control Center circuit (8) has electric power signal input end, pilot signal input end and cold signal input part,
The electric power signal output terminal of described oil-electric engine group (1) is connected with the electric power signal input end of electric energy detection device (7),
The first electric power signal output terminal of electric energy detection device (7) is connected with the electric power signal input end of electrical network feedback circuit (2),
The second electric power signal output terminal of electric energy detection device (7) is connected with the electric power signal input end of IDC Data Control Center circuit (8),
The pilot signal output terminal of oil-electric engine group (1) is connected with the oil-electric engine group pilot signal input end of supervisory circuit (4),
The pilot signal output terminal of supervisory circuit (4) is connected with the pilot signal input end of IDC Data Control Center circuit (8),
The power system monitor signal input part of supervisory circuit (4) is connected with the electric power signal output terminal of electrical network (3),
The electric power signal input end of electrical network (3) is connected with the electric power signal output terminal of electrical network feedback circuit (2),
The heat energy signal output part of oil-electric engine group (1) is connected with the heat energy signal input part of heat energy distributor (5),
The first heat energy signal output part of heat energy distributor (5) is connected with the heat energy signal input part of lithium bromide refrigerating device (6),
The second heat energy signal output part of heat energy distributor (5) is connected with the heat energy signal input part of heat output unit (10),
The first cold signal output part of lithium bromide refrigerating device (6) is connected with the cold signal input part of IDC Data Control Center circuit (8),
The second cold signal output part of lithium bromide refrigerating device (6) is connected with the cold signal input part of cold output unit (9).
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CN2013200423986U CN203012499U (en) | 2013-01-25 | 2013-01-25 | Cooling heating and power control system based on IDC data center |
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CN2013200423986U CN203012499U (en) | 2013-01-25 | 2013-01-25 | Cooling heating and power control system based on IDC data center |
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN103364211A (en) * | 2013-06-20 | 2013-10-23 | 华电电力科学研究院 | Comprehensive experiment device for natural gas distributed energy supply |
CN113133278A (en) * | 2021-03-25 | 2021-07-16 | 广州云硕科技发展有限公司 | Cold and hot control system of IDC data center |
CN114710929A (en) * | 2022-03-25 | 2022-07-05 | 利德世普科技有限公司 | Cold and hot control system of IDC data center |
-
2013
- 2013-01-25 CN CN2013200423986U patent/CN203012499U/en not_active Expired - Fee Related
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN103364211A (en) * | 2013-06-20 | 2013-10-23 | 华电电力科学研究院 | Comprehensive experiment device for natural gas distributed energy supply |
CN103364211B (en) * | 2013-06-20 | 2016-07-06 | 华电电力科学研究院 | A kind of Distribution of Natural formula energy supply comprehensive experimental device |
CN113133278A (en) * | 2021-03-25 | 2021-07-16 | 广州云硕科技发展有限公司 | Cold and hot control system of IDC data center |
CN114710929A (en) * | 2022-03-25 | 2022-07-05 | 利德世普科技有限公司 | Cold and hot control system of IDC data center |
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CF01 | Termination of patent right due to non-payment of annual fee | ||
CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20130619 Termination date: 20190125 |