JP2007322028A - Absorption type refrigerating system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide technology capable of efficiently generating cold heat. <P>SOLUTION: This absorption type refrigerating system comprises a first evaporator for cooling fluid by utilizing cold heat of cold water and evaporating the cold water at a low pressure, an absorber for cooling an absorbent by a cooling medium and allowing the absorbent to absorb the steam obtained by evaporating the cold water in the evaporator, a regenerator for heating a dilute absorbent obtained by allowing the absorbent to absorb the steam in the absorber to evaporate the water in the dilute absorbent and to release the steam, and returning the absorbent to the absorber, and power generating equipment including a condenser for condensing the steam released from the regenerator, a second evaporator for evaporating the water supplied from the condenser, a steam turbine driven by the steam obtained by evaporating the water by the second evaporator, and a power generator generating power by driving of the steam turbine. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a technology capable of efficiently generating cold heat, and particularly to an absorption refrigeration system including an absorption chiller and power generation equipment.

  Conventionally, an absorption refrigeration apparatus using an aqueous solution such as an aqueous solution of lithium bromide as an absorbent, and a plant and system including the same have been developed (see, for example, Patent Document 1).

However, conventional devices, plants, systems, and the like are not always satisfactory in terms of the efficiency of generating cold heat, and development of a technology that can efficiently generate cold heat is required.
JP 2002-89994 A

  Then, an object of this invention is to provide the technique which can generate cold efficiently.

  In order to solve the above-mentioned problems, an absorption refrigeration system according to the present invention uses a cold water to cool a fluid and cools the fluid at a low pressure, and a cooling medium to absorb the absorption liquid. And the absorber that absorbs the vapor obtained by evaporating the cold water in the evaporator, and the rare absorption liquid that absorbs the vapor in the absorber in the absorber A regenerator for evaporating water in the rare absorbent and releasing the vapor and returning the absorbent to the absorber; a condenser for condensing the vapor released from the regenerator; and the condenser A second evaporator for evaporating supplied water, a steam turbine driven by steam obtained by evaporating water in the second evaporator, and power generation by driving the steam turbine And a power generation facilities, including a generator.

  The absorption refrigeration system according to the present invention may further include a gas hydrate vaporizer that produces the cold water by vaporizing the gas hydrate. When the gas hydrate vaporized by the gas hydrate vaporizer is a hydrate of a combustible gas, using the combustible gas obtained by vaporizing the hydrate of the combustible gas, The regenerator may be provided with a heater that heats the rare absorbent. Further, when the absorber circulates a cooling medium to cool the absorption liquid, the absorption refrigeration system according to the present invention includes a heat of the cooling medium heated by the absorption liquid in the absorber. It is good also as providing the heat exchanger which warms the water which vaporizes the said gas hydrate using.

  The absorption refrigeration system according to the present invention further includes a heat exchanger that warms the rare absorbent that is heated by the regenerator using heat of the absorbent that is returned from the regenerator to the absorber. Also good.

  ADVANTAGE OF THE INVENTION According to this invention, the technique which can generate cold efficiently can be provided.

  Hereinafter, preferred embodiments will be described in detail with reference to the accompanying drawings.

  FIG. 1 shows a configuration diagram of an absorption refrigeration system described as an embodiment of the present invention. As shown in FIG. 1, the absorption refrigeration system 1000 according to the present invention includes an NGH vaporizer 100, an absorption chiller 200, a power generation facility 300, and the like.

  The NGH vaporizer 100 is an apparatus that opens a valve 110 to introduce water into the apparatus 100 and warms and vaporizes natural gas hydrate (NGH) with water. The NGH vaporizer 100 vaporizes NGH introduced into the apparatus 100 to produce cold water (vaporized water) and natural gas.

  The absorption refrigerator 200 is a device that uses cold water (vaporized water) generated by vaporizing NGH in the NGH vaporizer 100 as a refrigerant and generates cold by evaporating the cold water. As shown in FIG. 1, the absorption refrigerator 200 includes an evaporator 210, an absorber 220, a regenerator 230, heat exchangers 240 and 250, and the like.

  The evaporator 210 opens the valve 120 to pump the cold water (vaporized water) supplied from the NGH vaporizer 100 by the pump 212 and sprays it on the heat transfer tube 211 in a low pressure state (vacuum state: preferably 6 to 7 mmHg). In this device, the fluid flowing in the heat transfer pipe 211 is cooled by generating the cooling heat by the evaporation latent heat. The cooled fluid in the heat transfer tube 211 can be used for cooling or cooling.

  The absorber 220 was obtained by evaporating cold water in the evaporator 210 while being cooled with a cooling medium circulating (flowing) in the heat transfer tube 223 by the pump 222 by spreading the absorption liquid on the heat transfer tube 223. It is a device that absorbs vapor into the absorbing liquid. The cooling medium circulating in the heat transfer tube 223 is cooled by the cooling tower 221.

  The regenerator 230 is a device for regenerating an absorption liquid (a rare absorption liquid) whose concentration has been reduced by absorbing vapor in the absorber 220, and heats the rare absorption liquid supplied from the absorber 220 by the pump 224. Then, the water in the rare absorbent is evaporated, and the concentration of the absorbent is increased and returned to the absorber 220. In the present embodiment, the regenerator 230 uses the natural gas generated by vaporizing NGH in the NGH vaporizer 100 as fuel and heats the rare absorbent by the gas burner 231. However, the NGH vaporizer The rare absorbing liquid may be heated using exhaust heat obtained from a gas generator such as a gas turbine or a gas engine that generates power using the natural gas generated by vaporizing NGH at 100. Thereby, effective utilization of resources (combustible gas) and energy comes to be attained.

  The fluid is not particularly limited as long as it is not solidified by the cold heat of the cold water supplied from the NGH vaporizer 100. For example, a gas such as carbon dioxide or a liquid such as water is used. be able to. Moreover, as the above-mentioned cooling medium, any medium can be used as long as the absorbing liquid can be cooled. For example, cold water or the like can be used. As the above-mentioned absorbing liquid, any liquid can be used as long as it can absorb vapor obtained by evaporating cold water in the evaporator 210 and can evaporate water absorbed in the regenerator 230. For example, an aqueous solution of lithium bromide, an aqueous solution of lithium bromide to which a preservative such as chromic acid for preventing corrosivity, a heat transfer accelerator such as octyl alcohol for promoting heat transfer, and the like are added can be used.

  The heat exchanger 240 uses the heat of the absorption liquid returned from the regenerator 230 to the absorber 220 to heat the rare absorption liquid supplied from the absorber 220 to the regenerator 230 by the pump 224 and heated by the regenerator 230. Device. By providing this heat exchanger 240 in the absorption refrigerator 200, energy can be used effectively, so cooling of the absorbing liquid in the absorber 220 and heating of the rare absorbing liquid in the regenerator 230 can be performed with low energy. Will be able to do.

  The heat exchanger 250 circulates through the heat transfer tube 223 by the pump 222 and warms water that evaporates the natural gas hydrate using heat of a cooling medium that is warmed by providing cold energy to the absorbing liquid in the absorber 220. Device. By providing this heat exchanger 250 in the absorption refrigeration system 1000, the cold water for vaporizing NGH, which is introduced into the heat exchanger 250 by opening the valve 130 by effectively using energy, is warmed. It is possible to supply the NGH vaporizer 100 to efficiently vaporize NGH, or to cool the cooling medium circulating through the heat transfer tubes 223 in the heat exchanger 250 and reduce the cooling load on the cooling tower 221. In the present embodiment, the water that evaporates the natural gas hydrate is heated using the heat of the cooling medium warmed by cooling the absorbent in the absorber 220, but the regenerator 230 is used. It is good also as warming the water which vaporizes a natural gas hydrate using the heat | fever of the absorption liquid returned to the absorber 220 from.

  The power generation facility 300 is a power plant that generates power using high-temperature and high-pressure steam. As shown in FIG. 1, the power generation facility 300 includes a condenser 310, a boiler 320, a steam turbine 330, a generator 340, a pump 350, and the like.

  The boiler 320 is an evaporator that evaporates water and produces high-temperature and high-pressure steam. The steam turbine 330 is a device that is rotationally driven by steam generated by the boiler 320. The generator 340 is a device that produces electricity when the steam turbine 330 is rotationally driven. The condenser 310 is a condenser that condenses the low-temperature and low-pressure steam discharged from the steam turbine 330 and returns it to water (condensate). In the present embodiment, the vapor obtained by evaporating the water in the rare absorbent in the regenerator 230 is sucked into the condenser 310 without the power of a supply device such as a pump, and water is supplied to the power generation facility 300. The interior of the condenser 310 is kept in a vacuum state so that the sucked steam can be efficiently replenished and the sucked steam is efficiently converted into water. The pump 350 is a device that supplies water obtained by condensing the steam in the condenser 310 to the boiler 320.

  As described above, the absorption refrigeration system 1000 according to the present invention can spray clean cold water to the evaporator 210 in a low-pressure state (preferably in a vacuum state), and thus can efficiently generate cold heat. Therefore, the absorption refrigeration system 1000 according to the present invention has high cooling and cooling capabilities, and is useful for cooling systems and cooling systems.

  Further, in the absorption refrigeration system 1000 according to the present invention, clean cold water supplied to the evaporator 210 is absorbed by the absorption liquid in the absorber 220, separated from the absorption liquid by the regenerator 230, and supplied from a supply device such as a pump. Since water can be supplied to the power generation facility 300 without power, water lost in the steam turbine 330 of the power generation facility 300 can be replenished.

  Furthermore, by providing the absorption refrigeration system 1000 according to the present invention with the NGH vaporizer 100, not only can cold water generated by vaporizing NGH be used as a refrigerant for generating cold heat, but also power generation equipment 300 Since the natural gas produced by vaporizing NGH can be used as fuel, it is possible to effectively use NGH.

  In the present embodiment, the NGH vaporizer 100 vaporizes NGH with water introduced from the outside. However, the NGH vaporizer 100 may vaporize by heating and heating the NGH.

  In the present embodiment, cold water generated by vaporizing NGH is supplied to the evaporator 210 as a refrigerant. For example, cold water such as snowmelt or low-temperature river water (preferably 10 ° C. or lower) ) May be supplied to the evaporator 210 as a refrigerant. Thus, when using cold water such as snowmelt water or low-temperature river water as a refrigerant, the absorption refrigeration system 1000 is preferably provided with a water purifier that can purify the cold water in advance.

  Furthermore, in the above description, NGH is used as the fuel and the rare absorbing liquid in the regenerator 230 is heated. However, the rare absorbing liquid in the regenerator 230 is effectively used by exhaust heat of the power generation facility 300. It is good also as heating. As a result, the amount of natural gas used can be reduced.

  In the above description, a case where a single effect absorption refrigerator is used as the absorption refrigerator 200 has been described. However, in order to increase efficiency, a double effect absorption refrigerator or a triple effect absorption refrigerator is used. A multi-effect absorption refrigerator such as the above may be used.

  Below, as another embodiment, the case where the absorption refrigerator 200 is a double-effect absorption refrigerator will be described. FIG. 2 shows a schematic configuration of an absorption refrigeration system 1000 when the absorption chiller 200 is a double-effect absorption chiller. As shown in FIG. 2, the absorption refrigerator 200 includes an evaporator 210, an absorber 220, a low temperature regenerator 232, a steam boiler 235, a high temperature regenerator 234, heat exchangers 241, 242 and the like.

  The steam boiler 235 is an evaporator that heats supplied water to produce high-temperature steam. The low temperature regenerator 232 is a device that regenerates the rare absorbent supplied from the absorber 220 by the pump 224 at a low temperature. The high temperature regenerator 234 is a device that regenerates at a low temperature by the low temperature regenerator 232 and regenerates all or part of the rare absorbent supplied from the low temperature regenerator 232 by the pump 233 at a high temperature.

  In the present embodiment, the high temperature regenerator 234 uses the heat of steam generated by the steam boiler 235 to heat the rare absorbent supplied from the low temperature regenerator 232. The low temperature regenerator 232 uses the heat of steam obtained by regenerating the rare absorbent at a high temperature in the high temperature regenerator 234 (further produced by the steam boiler 235 and used in the high temperature regenerator 234. The heat of all or part of the vapor may also be used.) The rare absorbent supplied from the absorber 220 is heated. Thus, the steam used for heating the rare absorbent in the high temperature regenerator 234 and the low temperature regenerator 232 is sucked into the condenser 310 and used in the power generation facility 300.

  The heat exchanger 242 is a device that uses the heat of the absorbent regenerated at a high temperature in the high temperature regenerator 234 to heat the absorbent regenerated at a low temperature in the low temperature regenerator 232 and supplied to the high temperature regenerator 234 by the pump 233. is there. The heat exchanger 241 uses the heat of the absorption liquid regenerated at a high temperature in the high temperature regenerator 234 (when a part of the absorption liquid regenerated at a low temperature in the low temperature regenerator 232 is returned to the absorber 220, this absorption The heat of the liquid may be used.) A device that warms the rare absorbent supplied from the absorber 220 to the low temperature regenerator 232 by the pump 224. By providing the heat exchangers 241 and 242 in the absorption refrigerator 200 as described above, it is possible to save energy by effectively using energy.

  In the above description, the case of using NGH has been described. However, in place of NGH, flammable gas hydrate such as methane hydrate, ethane hydrate, and propane hydrate, nitrogen gas hydrate, oxygen gas hydrate, air A gas hydrate such as hydrate, or a mixture thereof may be used.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows schematic structure of the absorption refrigeration system provided with the single effect absorption refrigeration machine and electric power generation equipment demonstrated as one Embodiment of this invention. In one Embodiment of this invention, it is a figure which shows schematic structure of an absorption refrigeration system in case an absorption refrigeration machine is a double effect absorption refrigeration machine.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 NGH vaporizer 110-130 Valve 200 Absorption-type refrigerator 210 Evaporator 211,223 Heat-transfer tube 212,222,224,233,350 Pump 220 Absorber 221 Cooling tower 230 Regenerator 231 Gas burner 232 Low-temperature regenerator 234 High-temperature regenerator 235 Steam boiler 240, 241, 242, 250 Heat exchanger 300 Power generation facility 310 Condenser 320 Boiler 330 Steam turbine 340 Generator 1000 Absorption refrigeration system

Claims (5)

A first evaporator for cooling the fluid using the cold heat of the cold water and evaporating the cold water at a low pressure;
An absorber that cools the absorbing liquid with a cooling medium and that absorbs the vapor obtained by evaporating the cold water in the evaporator into the absorbing liquid;
A regenerator that heats a rare absorbent in which the vapor is absorbed in the absorbent in the absorber, evaporates water in the rare absorbent, releases the vapor, and returns the absorbent to the absorber; ,
By a condenser for condensing the steam released from the regenerator, a second evaporator for evaporating water supplied from the condenser, and a steam obtained by evaporating water in the second evaporator A power generation facility comprising: a steam turbine to be driven; and a generator for generating power by driving the steam turbine;
An absorption refrigeration system comprising:   The absorption refrigeration system according to claim 1, further comprising a gas hydrate vaporizer that produces the cold water by vaporizing a gas hydrate. The gas hydrate is a flammable gas hydrate;
The said regenerator is equipped with the heater which heats the said rare absorption liquid using the said combustible gas obtained by vaporizing the hydrate of the said combustible gas. Absorption refrigeration system. The absorber circulates a cooling medium that cools the absorbing liquid,
The heat exchanger which warms the water which vaporizes the gas hydrate using the heat of the cooling medium warmed by the absorption liquid in the absorber is further provided. Absorption refrigeration system. 5. The heat exchanger according to claim 1, further comprising a heat exchanger that heats the rare absorbent that is heated by the regenerator using heat of the absorbent that is returned from the regenerator to the absorber. Absorption refrigeration system according to crab.

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