TWI691831B - Energy-saving data center - Google Patents

Abstract

An energy-saving data center includes a heat generating unit, an exhaust duct, a casing, and a power generating unit. The heat generating unit generates heat upon power-on. The exhaust duct is configured to exhaust air. The casing is configured to receive the heat generating unit, and the housing is communication with the exhaust duct by a vent. The housing further defines an air inlet at an end of the housing away from the vent. The power generating unit is arranged in the exhaust duct and provides electric energy to the heat generating unit. The air inlet of the casing introduces cold air. The cold air flows through the heat generating unit to dissipate heat of the heat generating unit to become hot air. The hot air enters into the exhaust duct by the vent, and drives the power generating unit to generate Electrical energy.

Description

Energy Saving Information Center

The invention relates to an energy-saving data center.

With the rapid development of large data, the size of the data center's computer room is getting larger and larger, and a lot of heat will be generated during the operation of the data center.

In the prior art, air cooling technology is generally used to radiate heat to the cabinets of the data center. However, the heat generated by these cabinets is directly discharged to the outside, which cannot form a loop of energy utilization.

In view of this, it is necessary to provide an energy-saving data center that can improve energy efficiency.

An energy-saving data center includes a heating unit that generates heat when powered on. The energy-saving data center also includes: an exhaust duct for exhausting air; a housing for accommodating the heating unit. The casing communicates with the exhaust duct through a vent, and the end of the casing away from the vent is provided with an air inlet; a power generating unit is provided in the exhaust duct and is the heating unit Provide electrical energy; A cold wind is introduced into the air inlet of the casing, and the cold wind flows through the heat generating unit to radiate heat to the heat generating unit to form hot wind, and the hot wind enters the exhaust duct through the vent to drive the power generation unit to generate Electrical energy.

The above energy-saving data center generates hot wind by the heat generating unit, the hot wind generates wind force when the exhaust duct is discharged, the power generating unit generates electrical energy under the drive of the wind force, and supplies power to the heat generating unit . In this way, the energy utilization rate can be improved, thereby saving costs.

100: Energy Saving Information Center

10: Shell

12: Air inlet

14: Vent

20: heating unit

30: exhaust duct

40: Power generation unit

50: rectifier

60: heat collecting unit

62: collector

64: radiator

66: heat pipe

70: heating device

80: auxiliary heat zone

82: the first opening

84: second opening

90: Public grid

FIG. 1 is a schematic structural diagram of a preferred embodiment of an energy-saving data center of the present invention.

The technical solutions in the embodiments of the present invention will be described clearly and completely in the following with reference to the drawings in the embodiments of the present invention. Obviously, the described embodiments are part of the embodiments of the present invention rather than all the embodiments.

In order to make the objectives, technical solutions and advantages of the present invention more clear, the following will combine the drawings and the embodiments to further describe and explain the energy saving data center in the present invention.

Please refer to FIG. 1. In a preferred embodiment of the present invention, an energy-saving data center 100 includes a housing 10, a heating unit 20, an exhaust duct 30 and a power generating unit 40. The housing 10 is fixedly connected to one end of the exhaust duct 30, and the power generating unit 40 is disposed in the exhaust duct 30.

The housing 10 may be a container, a computer room, or a building module. A vent 14 is provided at the connection between the housing 10 and the exhaust duct 30, and an air inlet 12 is provided at the end of the housing 10 away from the vent 14.

The heating unit 20 generates heat when it is powered on. The heating unit 20 may be an electronic device such as a server, a storage device, or a communication device. The heating unit 20 is disposed in the housing 10.

The casing 10 introduces cold wind through the air inlet 12, and the cold wind flows through the heating unit 20 to radiate heat to the heating unit 20 to form hot air. The hot air flows to the vent 14 and enters the exhaust duct 30 through the vent 14.

Since the density of the hot air entering the exhaust duct 30 through the vent 14 is lower than the density of the air outside the exhaust duct 30, the hot air in the exhaust duct 30 flows upward and discharges the Vent duct 30. The wind force of the hot air during the discharge process can drive the power generating unit 40 to generate electric energy. It can be understood that under the same conditions, the greater the difference in density between the hot air in the exhaust duct 30 and the air outside the exhaust duct 30, the greater the wind power of the hot air during the exhaust process. The greater the amount of hot air in the exhaust duct 30, the greater the wind force during the exhaust of the hot air.

The power generating unit 40 is electrically connected to the heating unit 20 to provide electrical energy for the heating unit 20. The power generating unit 40 may be a wind power generator.

In this embodiment, the number of the housing 10 is two, and the two housings 10 are oppositely arranged. The exhaust duct 30 is vertically connected between the two housings 10. In other embodiments, the number of the housings 10 may also be greater than two, and these housings 10 are disposed around the exhaust duct 30 with the exhaust duct 30 as the center, and are connected to the exhaust duct 30 Connected. The number of the housing 10 can be adjusted according to actual needs.

As a preferred solution, the energy-saving data center 100 further includes a rectifier device 50 electrically connected between the power generation unit 40 and the heating unit 20, and the rectifier device 50 is also connected to the public power grid 90. connection.

The rectifier device 50 is used to process the electric energy transmitted by the power generation unit 40 and the public power grid 90, so as to output stable electric power to supply power to the heating unit 20. The rectifying device 50 is also used to process the electrical energy output by the power generation unit 40 to the public power grid 90, so that the power generation unit 40 can transmit excess electrical energy to the public power grid 90.

The rectifying device 50 is also used to determine whether the electrical energy generated by the power generation unit 40 meets the power supply requirement of the heating unit 20, and correspondingly control the power supply mode of the heating unit 20 according to the determination result.

Specifically, when the electrical energy generated by the power generation unit 40 meets the power supply demand of the heating unit 20, the heating unit 20 will be directly powered by the power generation unit 40 and output excess electrical energy to the public Grid 90 for sale. When the electrical energy generated by the power generation unit 40 cannot meet the power supply requirements of the heat generating unit 20, the heat generating unit 20 will be jointly powered by the power generating unit 40 and the public power grid 90.

The energy-saving data center 100 further includes a heat collecting unit 60, and the heat collecting unit 60 includes a heat collector 62, a radiator 64, and a heat pipe 66.

The heat collector 62 is connected to the heat sink 64 via a heat pipe 66. The heat collector 62 is installed outdoors to collect solar heat. The heat conducting tube 66 is provided with a heat conducting medium (not shown) for transmitting the solar heat collected by the heat collector 62 to the heat sink 64. The radiator 64 is disposed between the power generation unit 40 and the vent 14 for dissipating the solar heat. The temperature of the hot air at the bottom of the exhaust duct 30 increases, thereby increasing the density difference between the hot air and the air outside the exhaust duct 30. In this way, the upward wind force generated by the hot wind increases, thereby increasing the electrical energy generated by the power generation unit 40.

In a preferred embodiment, the energy-saving data center 100 may further include a heating device 70 and an auxiliary heating zone 80. The auxiliary heat zone 80 is disposed at the end of the housing 10 where the vent 14 is provided, and is disposed corresponding to the bottom of the exhaust duct 30. A first opening 82 is provided at the connection between the auxiliary heat zone 80 and the exhaust duct 30, and a second opening 84 is provided at an end of the auxiliary heat zone 80 away from the first opening 82. The heating device 70 is disposed between the first opening 82 and the second opening 84. The heating device 70 is used to heat the cold air entering through the second opening 84 to form hot air, and the hot air enters the exhaust duct 30 through the first opening 82. The hot air will increase the air volume and temperature of the hot air at the bottom of the exhaust duct 30. In this way, the hot wind at the bottom of the exhaust duct 30 generates an upward wind force, which further increases the electrical energy generated by the power generation unit 40.

In a preferred embodiment, the heating method of the heating device 70 may be a chemical reaction method (such as combustion). In other embodiments, the heating method of the heating device 70 may also be a mechanical compression method (such as cylinder compression).

In this embodiment, the exhaust duct 30 is a chimney.

The above energy-saving data center 100 generates hot air by heat dissipation of the heating unit 20, and the wind generated during the exhaust of the hot air. The power generating unit 40 generates electric energy under the driving of the wind, and supplies power to the heat generating unit 20. In this way, the energy utilization rate can be improved, thereby saving costs.

In summary, the present invention meets the requirements of the invention patent, and the patent application is filed in accordance with the law. However, the above are only the preferred embodiments of the present invention, and the scope of the present invention is not limited to the above-mentioned embodiments. Any modification or change made by those familiar with the skills of this case with the spirit of the present invention shall be It should be covered by the following patent applications.

100: Energy Saving Information Center

10: Shell

12: Air inlet

14: Vent

20: heating unit

30: exhaust duct

40: Power generation unit

50: rectifier

60: heat collecting unit

62: collector

64: radiator

66: heat pipe

70: heating device

80: auxiliary heat zone

82: the first opening

84: second opening

90: Public grid

Claims (9)

An energy-saving data center includes a heat-generating unit that generates heat when powered on, wherein the energy-saving data center further includes: an exhaust duct for exhausting air; a housing for accommodating the heating unit , The casing communicates with the exhaust duct through a vent, and the end of the casing away from the vent is provided with an air inlet; a power generating unit is provided in the exhaust duct and is The heating unit provides electrical energy; the air inlet of the casing introduces cold wind, which flows through the heating unit to radiate heat to the heating unit to form hot air, which enters the exhaust duct through the vent and drives The power generation unit generates electrical energy; wherein, the energy-saving data center further includes an auxiliary heat zone, which is provided at the end of the housing where the vent is provided and corresponds to the bottom of the exhaust duct. A first opening is provided at the connection between the auxiliary heat zone and the exhaust duct, and a second opening is provided at an end of the auxiliary heat zone away from the first opening. The energy-saving data center according to item 1 of the patent application scope, wherein the energy-saving data center further includes a rectifier device, the rectifier device is electrically connected between the power generation unit and the heating unit, and the rectifier device Electrically connected to the public power grid, the rectifier device is used to process the electrical energy transmitted by the power generation unit and the public power grid, thereby outputting stable power to supply power to the heating unit. The energy saving data center as described in item 2 of the patent application scope, wherein the rectifier is also used to determine whether the electrical energy generated by the power generation unit meets the power supply demand of the heating unit, and correspondingly control the The power supply of the heating unit; when the power generated by the power generation unit meets the power supply requirements of the heat generation unit, the heat generation unit will be directly powered by the power generation unit; when the power generated by the power generation unit cannot meet the When the power supply demand of the heating unit is mentioned, the power generation unit and the public power grid will jointly supply power to the heating unit. The energy saving data center according to item 3 of the patent application scope, wherein, when the power generated by the power generation unit satisfies the power supply demand of the heating unit, the rectifier device is also used to surplus power generated by the power generation unit Process and transfer to the public grid. The energy-saving data center as described in item 1 of the patent application scope, wherein the energy-saving data center further includes a heat collecting unit, the heat collecting unit includes a heat collector, a radiator and a heat pipe, the heat collector is A heat pipe is connected to the heat sink, the heat collector is arranged outdoors for collecting solar heat, the heat pipe is used to transmit the solar heat collected by the heat collector to the heat sink, the heat dissipation The generator is disposed between the power generation unit and the vent, for dissipating the solar heat. The energy-saving data center according to item 1 of the patent application scope, wherein the energy-saving data center further includes a heating device, and the heating device is disposed between the first opening and the second opening for The cold wind entering through the second opening is heated to form hot wind. The energy saving data center as described in item 6 of the patent application scope, wherein the heating method of the heating device is a chemical reaction method or a mechanical compression method. The energy saving data center as described in item 1 of the patent application scope, wherein the exhaust duct is a chimney. The energy saving data center according to item 1 of the patent application scope, wherein the number of the housings is two, the two housings are arranged oppositely, and the exhaust duct is vertically connected between the two housings.

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