KR20110037589A - Hybrid ocean thermal energy conversion system using waste heat of computer server - Google Patents

Abstract

PURPOSE: A seawater temperature difference power generating system using waste heat of a computer server is provided to produce electricity using temperature difference between deep sea water and surface sea water. CONSTITUTION: A seawater temperature difference power generating system using waste heat of a computer server comprises a water-cooling computer server(110), a pump unit(122), an electronic generate unit, and a seawater temperature difference generator(120). The water-cooling computer server comprises a heat exchanger(112). The heat exchanger raises the temperature of the surface sea water and lowers the temperature of the computer server. The pump unit pumps the surface sea water and the deep sea water. The electronic generate unit produces electricity using the temperature difference between the deep sea water and the surface sea water. The seawater temperature difference generator comprises a discharge unit.

Description

HYBRID OCEAN THERMAL ENERGY CONVERSION SYSTEM USING WASTE HEAT OF COMPUTER SERVER}

The disclosed technique relates to a seawater temperature difference generation system, and more particularly to an improved seawater temperature difference generation system using waste heat of a computer server.

Ocean Thermal Energy Conversion (OTEC) is a power generation method that generates electricity by using temperature differences between surface and deep ocean waters. Seawater temperature differentials are not economically feasible because of their low efficiency in areas where the surface temperature of ocean surface water is low or the temperature difference between ocean surface and deep water is low depending on the season.

Among the embodiments, the improved open-loop seawater temperature difference generation system using the waste heat of the computer server includes at least one water-cooled computer server including a heat exchanger for raising the surface temperature of the sea surface water and lowering the temperature inside the computer server by using the waste heat of the computer server. And seawater temperature difference generators. The open-loop seawater temperature difference generator generates electricity by using a temperature difference between the ocean surface water discharged from the heat exchange unit and the ocean surface water discharged from the heat exchange unit, respectively, a pump unit for raising the ocean surface water in the ocean surface and the ocean deep water in the ocean depth. A generation unit and a discharge unit for discharging the deep sea water and the deep sea water discharged after the electricity is generated.

Among the embodiments, the improved closed-loop seawater temperature difference generation system using the waste heat of the computer server includes at least one water-cooled computer server including a heat exchanger for raising the temperature of the circulating cooling fluid and lowering the temperature inside the computer server using the waste heat of the computer server. And seawater temperature difference generators. The closed-circuit seawater temperature difference generator generates electricity by using a pump unit for raising deep ocean water in the deep ocean, a temperature difference between the circulating cooling fluid discharged from the heat exchange unit and the deep ocean water, and transferring the circulating cooling fluid to the heat exchange unit. An electricity generating unit for re-introducing and a discharge unit for discharging the deep sea water discharged after the electricity is generated to the sea.

Description of the disclosed technology is only an embodiment for structural or functional description, the scope of the disclosed technology should not be construed as limited by the embodiments described in the text. That is, the embodiments may be variously modified and may have various forms, and thus the scope of the disclosed technology should be understood to include equivalents capable of realizing the technical idea.

1 is a block diagram illustrating an open circuit seawater temperature difference generation system using waste heat of a computer server according to an embodiment of the disclosed technology.

Referring to FIG. 1, the open-circuit seawater temperature difference generation system 100 using waste heat of a computer server includes a computer server 110, a seawater temperature difference generator 120, an ocean surface water inflow pipe 130, and an ocean deep water inflow pipe 140. And a discharge pipe 150.

The seawater temperature difference generation system 100 adopts an open-circuit system to lower the temperature inside the computer server 110 with the surface water drawn up from the sea and to generate the seawater temperature difference with the sea surface water heated by the computer server 110. Discharge surface waters to the ocean.

Computer server 110 may be connected to the Internet or satellite, and client computers may connect to computer server 110 via the Internet. Therefore, the computer server center does not need to be located in a large metropolitan area where users can be installed, and can be installed in a coastal area adjacent to the seawater temperature difference generating facility. The computer server 110 includes a heat exchanger 112 that lowers the internal temperature of the computer server 110 through the surface water introduced from the ocean. The heat exchanger 112 exchanges heat between the ocean surface water and the inside of the computer server 110 to raise the temperature of the ocean surface water and lower the temperature inside the computer server 110. In one embodiment, one or more heat exchangers 112 may be included, depending on the number of computer servers 110.

The seawater temperature difference generator 120 generates electricity by using a temperature difference between the surface water of the sea and the deep water of the sea, heated by the computer server 110. The seawater temperature difference generator 120 includes a pump unit 122, an evaporator 124, a turbine generator 126, and a condenser 128, and the pump unit 122 includes a first pump 121 and a second pump 123. ).

The pump unit 122 raises the ocean surface water at the ocean surface and the ocean deep water at the ocean depth. The first pump 121 pulls up the surface water of the sea (hereinafter, referred to as the first high temperature of the surface water of the sea) through the surface water inlet pipe 130. The first high temperature sea surface water flows into the heat exchanger of the computer server 110. The first high-temperature sea surface water is sea water between about 15 to 25 ° C., and is distributed over the sea surface up to about 200 m.

The heat exchanger 112 of the computer server 110 heats the first high temperature sea surface water to about 40-50 ° C. through heat exchange between the first high temperature sea surface water and the computer server 110 (hereinafter, 2 hot surface water). The higher the temperature of the second hot ocean surface water, the higher the seawater temperature difference generation efficiency.

Evaporator 124 heats the working fluid through heat exchange between the second hot ocean surface water and the working fluid. The working fluid may use a low temperature boiling medium (or refrigerant) that vaporizes at low temperatures, and the state of the heated working fluid may correspond to the vaporized state. In one embodiment, the low temperature boiling medium may comprise ammonia or propylene that does not destroy the ozone layer. Through heat exchange, the surface water of the ocean (hereinafter referred to as the third high temperature marine surface water) of about 35 to 45 ° C. discharged from the evaporator 124 may be discharged to the sea through the discharge pipe 150, and the vaporized working fluid Flows into the turbine generator 126.

Turbine generator 126 generates electricity by rotating the turbine with vaporized working fluid. In one embodiment, when the vaporized working fluid rotates the turbine, turbine generator 126 may generate electricity from the turbine's rotational energy. The working fluid enters the condenser 128 via the turbine generator 126.

The second pump 123 pulls up deep sea water (hereinafter, deep sea water at a first low temperature) through the deep sea water inflow pipe 140. The first low temperature deep sea water flows into the condenser 128. The deep sea water at the first low temperature is the sea water at about 4 ° C., and is distributed in the deep sea water of about 200 m or less.

Condenser 128 cools the working fluid through heat exchange between the first low temperature deep sea water and the working fluid. In one embodiment, the state of the cooled working fluid may correspond to the liquefied state. Through heat exchange, the second low temperature deep sea water (about 4.5 ° C.) discharged from the condenser 128 is discharged to the sea through the discharge pipe 150, and the liquefied working fluid flows back into the evaporator 124.

FIG. 2 is a block diagram illustrating the open circuit seawater temperature difference generator of FIG. 1.

Referring to FIG. 2, the seawater temperature difference generator includes a pump unit 122, an evaporator 124, a turbine generator 126, a condenser 128, a third pump 230, and a discharge unit 240. 122 includes a first pump 121 and a second pump 123.

The pump unit 122 and the evaporator 124 are the same as the description of FIG. 1 listed above.

The turbine generator 126 includes a turbine 210 and a generator 220. When the vaporized working fluid rotates the turbine 210, the generator 220 generates electricity by the rotational energy of the turbine 210. The working fluid enters the condenser 128 via the turbine generator 126.

The second low temperature deep sea water discharged after the heat exchange in the condenser 128 may be discharged to the discharge unit 240, and the cooled working fluid is introduced into the evaporator 124 through the third pump 230.

The discharge part 240 mixes the third high temperature marine surface water discharged from the evaporator 124 and the second low temperature deep ocean water discharged from the condenser 128 and discharges it to the ocean. This is to preserve the marine environment by minimizing the difference between the temperature of the discharged water and the water temperature in the discharged area.

3 is a block diagram illustrating a process of introducing ocean surface water into a plurality of computer servers when there are a plurality of computer servers of FIG. 2.

Referring to FIG. 3, the seawater temperature difference generator includes a distribution unit 310, a control unit 320, a comprehensive storage unit 330, and a pump 340.

The distribution unit 310 distributes the first high temperature marine surface water drawn up through the first pump 121. The first control unit 320a includes a first storage unit 322a and a first flow rate control unit 324a. The first controller 320a adjusts the amount of the first high temperature ocean surface water flowing into the first computer server 110a based on the internal temperature of the first computer server 110a.

The first reservoir 322a stores the first high temperature ocean surface water distributed by the distribution unit 310. The first flow controller 324a supplies at least a portion of the first high temperature ocean surface water stored in the first reservoir 322a to the first computer server 110a based on the internal temperature of the first computer server 110a. Flow it in. When the internal temperature of the first computer server 110a is high, the first flow rate controller 324a increases the amount of the first high temperature ocean surface water flowing into the first computer server 110a.

The second control unit 320b, the n-th control unit 320c, and the n-th control unit 320d play the same role as the first control unit 320a.

Each computer server 110 includes a heat exchanger 112, respectively. Each heat exchanger 112 lowers the internal temperature of the computer server 110 through heat exchange between the first hot ocean surface water introduced from each controller 320 and the inside of the computer server 110.

The comprehensive reservoir 330 stores the second hot ocean surface water heated and discharged through each computer server 110. The pump 340 introduces the second hot sea surface water stored in the comprehensive reservoir 330 into the evaporator 124.

4 is a block diagram illustrating a closed circuit seawater temperature difference generation system using waste heat of a computer server according to another exemplary embodiment of the disclosed technology.

Referring to FIG. 4, a closed circuit seawater temperature difference generation system 400 using waste heat of a computer server includes a computer server 410, a seawater temperature difference generator 420, a deep sea water inflow pipe 430, and a discharge pipe 440.

The seawater temperature difference generation system 400 adopts a closed circuit system to circulate a circulating cooling fluid between the computer server 410 and the seawater temperature generator 420 to form a closed circuit. The advantage of this method is that no inflow of ocean surface water is required.

The computer server 410 includes a heat exchanger 412 that lowers the internal temperature of the computer server 410 through the circulating cooling fluid. The circulating cooling fluid circulates between the computer server 410 and the seawater temperature difference generator 420 and exchanges heat. The circulating cooling fluid may use propane, butane, ammonia, carbon dioxide, and the like which are easy to heat exchange and have excellent efficiency.

The heat exchanger 412 of the computer server 410 raises the temperature of the circulating cooling fluid and lowers the temperature inside the computer server 410 through heat exchange between the circulating cooling fluid and the inside of the computer server 410. In one embodiment, one or more heat exchangers 412 may be included, depending on the number of computer servers 410.

The seawater temperature generator 420 includes an evaporator 422, a turbine generator 424, a condenser 426, and a pump unit 428. The seawater temperature difference generator 420 generates electricity by using a temperature difference between the circulating cooling fluid heated by the computer server 410 and the deep sea water.

Since the functions of the evaporator 422, the turbine generator 424, and the condenser 426 are substantially the same as the open circuit system, description thereof will be omitted.

The pump unit 428 raises the first deep sea water at a low temperature through the deep sea water inflow pipe 430, and introduces the deep sea water into the condenser 426.

5 is a block diagram illustrating the closed-circuit seawater temperature difference generator of FIG. 4.

Referring to FIG. 5, the seawater temperature difference generator includes an evaporator 422, a turbine generator 424, a condenser 426, a pump unit 428, a second pump 530, and an outlet 540.

The low temperature circulating cooling fluid discharged from the evaporator 422 flows back into the computer server 410, and the vaporized working fluid flows into the turbine generator 424.

The turbine generator 424 includes a turbine 510 and a power generation unit 520. When the vaporized working fluid rotates the turbine 510, the power generation unit 520 generates electricity by the rotational energy of the turbine 510. The working fluid enters the condenser 426 via the turbine generator 424.

The condenser 426 discharges deep sea water to the discharge part 540 after heat exchange.

The second pump 530 introduces the working fluid cooled in the condenser 426 back to the evaporator 422, and the discharge part 540 discharges the second low temperature deep sea water discharged from the condenser 426 back into the deep sea. do.

6 is a block diagram illustrating a process of introducing a circulating cooling fluid into a plurality of computer servers when a plurality of computer servers of FIG. 5 are used.

Referring to FIG. 6, the seawater temperature difference generator includes a distribution unit 610, a control unit 620, a comprehensive storage unit 630, and a pump 640.

The distribution unit 610 distributes the low temperature circulating cooling fluid. The first controller 620a includes a first reservoir 622a and a first flow controller 624a and flows into the first computer server 410a based on an internal temperature of the first computer server 410a. Adjust the amount of low temperature circulating cooling fluid. Since the functions of the reservoir 622 and the flow rate controller 624 are substantially the same as those described with reference to FIG. 3, description thereof will be omitted.

The second control unit 620b, the n-th control unit 620c, and the n-th control unit 620d play the same role as the first control unit 620a.

The comprehensive reservoir 630 stores the high temperature circulating cooling fluid that is heated and discharged through each computer server 410. The pump 640 introduces a high temperature circulating cooling fluid stored in the comprehensive reservoir 630 into the evaporator 422.

7 is a flowchart illustrating a method for generating an open circuit seawater temperature difference using waste heat of a computer server according to an exemplary embodiment of the disclosed technology.

The seawater temperature difference generator pulls up the first high temperature marine surface water and the first low temperature deep ocean water from the surface and deep layers of the ocean through the pump unit (S700). The first hot ocean surface water drawn up through the pump portion enters the heat exchange portion of the computer server. In one embodiment, the seawater temperature differential generator may adjust the amount of first hot ocean surface water entering the computer server based on the temperature inside the computer server. When there are a plurality of computer servers, the seawater temperature difference generator may adjust the amount of the first high temperature ocean surface water flowing into each computer server based on the temperature inside each computer server.

The heat exchanger of the computer server raises the temperature of the first high temperature marine surface water through heat exchange between the first high temperature marine surface water and the inside of the computer server (S710). The seawater temperature difference generator generates electricity by using a temperature difference between the second high temperature sea surface water and the first low temperature deep sea water (S720).

For example, a seawater temperature differential generator heats the working fluid through heat exchange between the second hot ocean surface water and the working fluid, and rotates the turbine with the vaporized working fluid to generate electricity. The sea water temperature generator cools the working fluid through heat exchange between the first low temperature deep sea water and the working fluid passed through the turbine generator, and introduces the liquefied working fluid back into the evaporator.

The seawater temperature difference generator generates electricity and mixes the discharged third high temperature marine surface water and the second low temperature deep sea water to the ocean (S730).

8 is a flowchart illustrating a method for generating a closed circuit seawater temperature difference using waste heat of a computer server according to another exemplary embodiment of the disclosed technology.

The seawater temperature difference generator raises the first deep sea water at a low temperature from the deep sea through a pump (S800). The heat exchanger of the computer server raises the temperature of the low-temperature circulating cooling fluid through the heat exchange between the low-temperature circulating cooling fluid and the inside of the computer server, and lowers the temperature of the computer server (S810).

The seawater temperature generator generates electricity by using a temperature difference between the high temperature circulating cooling fluid discharged by being heated by the computer server and the first deep sea water at low temperature (S820).

For example, a seawater temperature differential generator heats a working fluid through heat exchange between a high temperature circulating cooling fluid and a working fluid, and generates electricity by rotating the turbine with a vaporized working fluid. The sea water temperature generator cools the working fluid through heat exchange between the cold deep sea water and the working fluid passing through the turbine generator, and introduces the liquefied working fluid back into the evaporator.

The seawater temperature difference generator generates electricity and introduces the low-temperature circulating cooling fluid into the computer server again (S830). In one embodiment, the seawater temperature difference generator may adjust the amount of circulating cooling fluid introduced into the computer server based on the temperature inside the computer server. When there are a plurality of computer servers, the seawater temperature difference generator may adjust the amount of circulating cooling fluid flowing into each computer server based on the temperature inside each computer server.

The seawater temperature difference generator generates electricity and then discharges the second deep sea water having been discharged back into the deep sea (S840).

The disclosed technique may have the following effects. It is to be understood, however, that the scope of the disclosed technology is not to be construed as limited thereby, as it is not meant to imply that a particular embodiment should include all of the following effects or only the following effects.

The seawater temperature difference generation system using the waste heat of the computer server according to an embodiment generates a seawater temperature difference generation temperature rise in the process of cooling the computer server using sea water can be expected to be higher efficiency than the conventional seawater temperature difference generation system.

In addition, the seawater temperature difference generation system using waste heat of the computer server can install a computer server center that is not geographically restricted in the adjacent sea area, and can cool the computer server stably by using abundant amount of seawater. The reduction in power generation efficiency due to temperature change or the reduction in power generation efficiency due to regional limitations can be reduced.

In addition, the effectiveness of the present technology is increased in that it can not only save a considerable amount of money for treating the heat generated when cooling the computer server, but also can recycle the waste heat in an environmentally friendly manner.

Although described above with reference to embodiments of the present invention, those skilled in the art will be able to variously modify and change the present invention without departing from the spirit and scope of the invention as set forth in the claims below. I can understand that it can.

1 is a block diagram illustrating an open circuit seawater temperature difference generation system using waste heat of a computer server according to an embodiment of the disclosed technology.

FIG. 2 is a block diagram illustrating the open circuit seawater temperature difference generator of FIG. 1.

3 is a block diagram illustrating a process of introducing ocean surface water into a plurality of computer servers when there are a plurality of computer servers of FIG. 2.

4 is a block diagram illustrating a closed circuit seawater temperature difference generation system using waste heat of a computer server according to another exemplary embodiment of the disclosed technology.

5 is a block diagram illustrating the closed-circuit seawater temperature difference generator of FIG. 4.

6 is a block diagram illustrating a process of introducing a circulating cooling fluid into a plurality of computer servers when a plurality of computer servers of FIG. 5 are used.

7 is a flowchart illustrating a method for generating an open circuit seawater temperature difference using waste heat of a computer server according to an exemplary embodiment of the disclosed technology.

8 is a flowchart illustrating a method for generating a closed circuit seawater temperature difference using waste heat of a computer server according to another exemplary embodiment of the disclosed technology.

Claims (6)

At least one water-cooled computer server comprising a heat exchanger for raising the surface temperature of the ocean surface water and lowering the temperature inside the computer server through heat exchange inside the computer server; A pump unit for raising the ocean surface water in the ocean surface and the ocean deep water in the ocean depth, an electricity generation unit for generating electricity by using the temperature difference between the ocean surface water discharged from the heat exchange unit and the ocean deep water, and the electricity price An improved open circuit seawater temperature difference generation system using waste heat from a computer server including a seawater temperature difference generator including a marine surface water discharged after generation and a discharge portion for discharging deep sea water. The method of claim 1, wherein the electricity generating unit An evaporator for vaporizing a working fluid through the sea surface water discharged from the heat exchange unit; A turbine generator for generating electricity through the vaporized working fluid; Improved open-loop seawater temperature difference generation system using the waste heat of the computer server including a condenser for cooling the working fluid passed through the turbine power generation unit through the deep ocean water. According to claim 1, wherein the sea water temperature difference generator A distribution unit for distributing the surface water drawn up by the pump unit to each of the at least one water-cooled computer server; And At least one control unit for adjusting the amount of surface water in the water flowing into the water-cooled computer server based on the internal temperature of the water-cooled computer server, The control unit A reservoir for storing ocean surface water introduced by the pump; And A flow control unit for introducing at least a portion of the stored ocean surface water into the at least one water-cooled computer server based on the internal temperature of the at least one water-cooled computer server. Improved open-loop seawater temperature difference generation system using the waste heat of the computer server further comprising. At least one water-cooled computer server comprising a heat exchanger for raising the temperature of the circulating cooling fluid and lowering the temperature inside the computer server through heat exchange; A pump unit for raising the deep sea water in the deep sea, the electricity generation unit for generating electricity by using the temperature difference between the circulating cooling fluid discharged from the heat exchanger and the deep sea water and discharge the circulating cooling fluid to the heat exchanger And a seawater temperature difference generator comprising a discharge unit for discharging deep ocean water discharged after the electricity is generated. The method of claim 4, wherein the electricity generating unit An evaporator for vaporizing a working fluid through the circulating cooling fluid discharged from the heat exchange unit; A turbine generator for generating electricity through the vaporized working fluid; And a condenser for cooling the working fluid that has passed through the turbine power generation unit through the deep ocean water. The method of claim 4, wherein the seawater temperature difference generator A distribution unit distributing a circulating cooling fluid to each of the at least one water-cooled computer server; And At least one control unit for adjusting the amount of circulating cooling fluid flowing into the water-cooled computer server based on the internal temperature of the water-cooled computer server, The control unit A reservoir for storing the circulating cooling fluid; And A flow rate controller for flowing at least a portion of the stored circulating cooling fluid to the at least one water-cooled computer server based on the internal temperature of the at least one water-cooled computer server Improved closed-loop seawater temperature difference generation system using the waste heat of the computer server further comprising.

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