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CN106787601A - For the heat accumulating type metal magnetic fluid generating device and method of electric energy peak load shifting - Google Patents

For the heat accumulating type metal magnetic fluid generating device and method of electric energy peak load shifting Download PDF

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Publication number
CN106787601A
CN106787601A CN201710006847.4A CN201710006847A CN106787601A CN 106787601 A CN106787601 A CN 106787601A CN 201710006847 A CN201710006847 A CN 201710006847A CN 106787601 A CN106787601 A CN 106787601A
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China
Prior art keywords
liquid metal
electric
blender
heat accumulator
pump
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Pending
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CN201710006847.4A
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Chinese (zh)
Inventor
郑星文
鹿鹏
李伟
黄护林
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Nanjing University of Aeronautics and Astronautics
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Nanjing University of Aeronautics and Astronautics
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Priority to CN201710006847.4A priority Critical patent/CN106787601A/en
Publication of CN106787601A publication Critical patent/CN106787601A/en
Pending legal-status Critical Current

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    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02KDYNAMO-ELECTRIC MACHINES
    • H02K44/00Machines in which the dynamo-electric interaction between a plasma or flow of conductive liquid or of fluid-borne conductive or magnetic particles and a coil system or magnetic field converts energy of mass flow into electrical energy or vice versa
    • H02K44/08Magnetohydrodynamic [MHD] generators
    • H02K44/085Magnetohydrodynamic [MHD] generators with conducting liquids
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F28HEAT EXCHANGE IN GENERAL
    • F28DHEAT-EXCHANGE APPARATUS, NOT PROVIDED FOR IN ANOTHER SUBCLASS, IN WHICH THE HEAT-EXCHANGE MEDIA DO NOT COME INTO DIRECT CONTACT
    • F28D20/00Heat storage plants or apparatus in general; Regenerative heat-exchange apparatus not covered by groups F28D17/00 or F28D19/00
    • F28D20/0034Heat storage plants or apparatus in general; Regenerative heat-exchange apparatus not covered by groups F28D17/00 or F28D19/00 using liquid heat storage material
    • 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
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E20/00Combustion technologies with mitigation potential
    • Y02E20/14Combined heat and power generation [CHP]
    • 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
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E60/00Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
    • Y02E60/14Thermal energy storage

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  • Engineering & Computer Science (AREA)
  • Physics & Mathematics (AREA)
  • Thermal Sciences (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Fluid Mechanics (AREA)
  • Power Engineering (AREA)
  • Engine Equipment That Uses Special Cycles (AREA)

Abstract

The invention discloses a kind of heat accumulating type metal magnetic fluid generating device and method for electric energy peak load shifting, its device is mainly made up of electric heater, electric heat accumulator, heater, magnetic fluid pump, blender, temperature controller, magnetohydrodynamic generator passage, separator, condenser and pump etc..Night, unnecessary electricity was supplied electric heat accumulator by power plant, and electric heat accumulator is in stage regenerator, it is to avoid the waste of night electric energy;Daytime, electric heat accumulator stopped accumulation of heat, the heat that night stores is supplied into liquid metal by conduction oil, liquid metal temperature is raised, there is vaporization, expansion after mixing with high temperature fluent metal in low boiling working fluid fluid, promote liquid metal flows, produce electric current to send electricity in power channel cutting magnetic induction line, reach the purpose of peak load shifting;And the TRT needs not move through mechanical switch link, directly converts heat energy into electric energy, design can be made simpler, reduce the cost of system, capacity usage ratio is higher.

Description

For the heat accumulating type metal magnetic fluid generating device and method of electric energy peak load shifting
Technical field
It is used for electric energy peak load shifting apparatus and method the present invention relates to one kind, more particularly to it is a kind of for electric energy peak load shifting Heat accumulating type metal magnetic fluid generating device and method, it belongs to energy-saving and emission-reduction field.
Background technology
The Demand-side of power system is made up of three class consumers, respectively industry, family and commercialization, family and commercial power Demand accounts for the overwhelming majority of total electricity consumption, and daily power consumption has obvious morning peak and evening peak and night dip, but The electricity that power plant was sent per the period is relatively-stationary, if power plant night unnecessary generated energy can be made full use of to supplement daytime The deficiency of generated energy, can be achieved with the purpose of generated energy peak load shifting, reduce the waste of the energy.
Thermal energy storage is realized to increase the interior energy of energy storage medium by way of heating, according to the shape of storage heat energy Formula is divided into sensible heat, latent heat and heat chemistry energy storage, and energy storage temperature is all hundreds of K up to 1000K or so, very polymetallic fusing point, because It is technically feasible that this makes metal keep liquid using the heat of energy storage medium.
Magnetohydrodynamic(MHD) generator mainly has two kinds of forms, high temperature plasma gas Magnetohydrodynamic(MHD) generator and liquid metal magnetohydrodynamic Generator (Liquid metal MHD abbreviation LMMHD), the former is as thermal source, with thermal ionization with oil, coal, natural gas etc. What gaseous conductor generated electricity for working medium, although the generating efficiency of it and Steam Combined Cycle is up to 50%~60%, but it is to heat Source temperature requirement is very high, generally in 3000K or so.
Liquid metal compares high-temperature gas, high with conductance, and specific heat is big, the advantages of heat source temperature is less demanding, due to Liquid metal viscosity is larger, therefore volatile fluid (such as toluene, ethane, vapor) is doped into liquid metal.These During liquid is once add liquid metal, bubble is boiled at once, the image of bubble multiple-piston pump of expansion equally promotes liquid metal Flow fast through power channel.Liquid metal magnetohydrodynamic generation system has advantages below:(1) still can be by when due to gas expansion Liquid metal is heated, and is similar to isothermal expansion, the direct contact heat transfer of gas and liquid metal is added, in same heat source temperature Under, its efficiency is at a relatively high;(2) magnetohydrodynamic generator passage needs not move through mechanical switch link, directly converts heat energy into Electric energy, can not only make design simpler, reduce the cost of system, and capacity usage ratio is higher;(3) selectable heat Source range is very big, both can be common coal, oil, natural gas, can also be nuclear energy, can also be poor using ability of doing work Thermal source, such as solar energy, industrial waste heat;(4) both can be able to be top, or low as the one-level in combined cycle Level, increased the scope of application, while combined cycle can improve the efficiency of system.
In the short term, the daily change of electric power output can be compensated by existing traditional power plants to a certain extent, But extra cost can be so produced, the inefficient underrun of the factor including frequent cycle of these costs and quick is produced Load increases, and this can cause to damage to generating equipment, so as to need to expend more maintenance costs etc., in these cases, night Between using energy storage device will unnecessary electricity be stored, daytime again discharges these energy and is converted to the way of electricity again and is It is considerable.From from the perspective of environment, postponing electricity consumption can turn the generated energy of low-carbon emission thermal source in the non-peak load period Moving on to the peak load period uses, so as to reduce the consumption to high-carbon energy, is conducive to carbon emission reduction.
The content of the invention
Goal of the invention:For above-mentioned prior art, the heat accumulating type liquid metal magnetohydrodynamic for electric energy peak load shifting is proposed TRT and method, realize the effect to electric energy peak load shifting.
Technical scheme:A kind of heat accumulating type metal magnetic fluid generating device for electric energy peak load shifting, including storage is put Hot systems, liquid metal magnetohydrodynamic generation system and hot-water heating system;
The storage thermal desorption system includes power plant, the first pump, heater and electric heat accumulator;Electric heat accumulator conduction oil outlet with First pump heat conduction oil-in connects, and the first pump conduction oil outlet is connected with heater heat conduction oil-in a, heater conduction oil outlet B is connected with electric heat accumulator heat conduction oil-in;The power plant night supplies electricity to electric heat accumulator, and daytime, electric heat accumulator passed through conduction oil Heat supply is to heater;
The liquid metal magnetohydrodynamic generation system includes that magnetic fluid pump, temperature controller, blender, electric heater, generating are logical Road, the second pump and separator;The heater liquid metal outlet d is connected with magnetic fluid pump liquid state metal inlet, magnetic fluid pump Liquid metal outlet is connected with blender liquid metal entrance e, and the outlet of blender fluid-mixing enters with power channel fluid-mixing Mouthful connection, power channel fluid-mixing outlet be connected with separator fluid-mixing entrance, separator liquid metal outlet g and heat Device liquid metal entrance c is connected;
The hot-water heating system includes condenser, cold water inlet pipe road and hot water delivery pipe road;The separator low boiling work Matter vapor outlet port h is connected with condenser low boiling working fluid vapour inlet i, and condenser low boiling working fluid exports j and pump low boiling work Matter entrance is connected, and the outlet of pump low boiling working fluid is connected with blender low boiling working fluid entrance f, the cold water inlet pipe road and condensation Device entrance k is connected, and condensator outlet l is connected with hot water delivery pipe road;Temperature controller is used for liquid metal in real-time monitoring blender Temperature, when liquid metal temperature is less than its fusing point in blender, electric heater is automatically turned on, it is ensured that liquid metal in blender Temperature is higher than its fusing point without solidifying.
A kind of heat accumulating type liquid metal magnetohydrodynamic generation method for electric energy peak load shifting, comprises the following steps:
Step 1, power plant night supplies electricity to electric heat accumulator, and the energy storage medium temperature of electric heat accumulator is raised, converted electrical energy into It is heat energy, electric heat accumulator is in the accumulation of energy stage;
Step 2, daytime, electric heat accumulator stopped accumulation of energy, and the heat in electric heat accumulator energy storage medium is absorbed by conduction oil, and Heater is passed to by pump to heat liquid metal, the conduction oil after temperature reduction returns to electric heat accumulator and absorbs energy storage matchmaker again Heat in matter, electric heat accumulator is in the exoergic stage;
Step 3, the heated device temperature after heating of liquid metal is raised, and is pumped into blender and low boiling by magnetic fluid Point working medium mixing, low boiling working fluid is vaporized and expands the dynamic liquid metal flows of pusher and enters MHD power channels, liquid metal flows Cutting magnetic induction line generates electricity;
Step 4, flow through the liquid metal after MHD power channels carries out two-phase laminated flow into separator, the liquid separated The heated device heating of state metal, and blender is again introduced into after the pressurization of magnetic fluid pump, the low boiling working fluid steam separated Liquid is condensed into condenser, blender is again introduced into after being then pressurized;One temperature controller real-time monitoring blender is set Middle liquid metal temperature, when liquid metal temperature is less than its fusing point, electric heater is automatically turned on, the liquid in heating mixer Metal.
Beneficial effect:(1) unnecessary is supplied electricity into electric heat accumulator heating when using night low power consumption, heat is converted electric energy to Can, it is to avoid the waste of night electric energy, the heat energy in electric heat accumulator is changed into electric energy again during external world's peak of power consumption on daytime, to meet User power utilization demand, realize effect of the device to electric energy peak load shifting, it is to avoid daytime, power plant was to meet extraneous electricity consumption need The consumption to high-carbon energy is asked, is conducive to carbon emission reduction;
(2) generating equipment inefficient underrun and quick load is increased during peak of power consumption in low power consumption is avoided Frequent cycle causes to damage to generating equipment, reduces the maintenance cost to equipment;
(3) TRT needs not move through mechanical switch link, directly converts heat energy into electric energy, can not only make design It is simpler, the cost of system is reduced, and also capacity usage ratio is higher;
(4) can return to boiler or as domestic water after the condensed device preheating of chilled water, can reduce add to a certain extent The energy consumption of hot water;
(5) the magnetohydrodynamic electricity generation system generating effect is notable, through numerical simulation calculation, the workflow of magnetohydrodynamic electricity generation system After body is promoted through low boiling working fluid vaporized expanding, speed lifts effect up to more than 3 times;
(6) present invention realizes compact conformation, good economy performance, the electric energy peak load shifting purpose of system stabilization, is conducive to section Can emission reduction, low-carbon environment-friendly.
Brief description of the drawings
Fig. 1 is structural representation of the present invention for the heat accumulating type metal magnetic fluid generating device of electric energy peak load shifting Figure;
Wherein:1- power plants;The pumps of 2- first;3- heaters;4- electric heat accumulators;5- magnetic fluid pumps;6- temperature controllers;7- mixes Device;8- electric heaters;9- power channels;10- pumps;11- separators;12- condensers;13- cold water inlet pipes road;14- cold water is defeated Go out pipeline;A- heater heat conduction oil-in;B- heater conduction oil outlets;C- heater liquid metal entrances;D- heater liquid State metal outlet;E- blender liquid metal entrances;F- blender low boiling working fluid entrances;G- separator liquid metal outlets; H- separator low boiling working fluid vapor outlet ports;I- condenser low boiling working fluid vapour inlets;J- condensers low boiling working fluid is exported; K- condenser cold water inlets;L- condenser hot water outlets.
Specific embodiment
The present invention is done below in conjunction with the accompanying drawings further is explained.
As shown in figure 1, a kind of heat accumulating type metal magnetic fluid generating device for electric energy peak load shifting, including storage is put Hot systems, liquid metal magnetohydrodynamic generation system and hot-water heating system.
Storing thermal desorption system includes power plant 1, pump 2, heater 3 and electric heat accumulator 4.Wherein, the conduction oil outlet of electric heat accumulator 4 It is connected with the heat conduction oil-in of pump 2, the conduction oil outlet of pump 2 is connected with the heat conduction oil-in a of heater 3, the conduction oil outlet b of heater 3 It is connected with the heat conduction oil-in of electric heat accumulator 4.The night of power plant 1 supplies electricity to electric heat accumulator 4, and daytime, electric heat accumulator 4 was by conduction oil Heat supply is to heater 3.
Liquid metal magnetohydrodynamic generation system includes that magnetic fluid pump 5, temperature controller 6, blender 7, electric heater 8, generating are logical Road 9, pump 10 and separator 11.The liquid metal outlet d of heater 3 is connected with the liquid metal entrance of magnetic fluid pump 5, magnetic fluid pump 5 Liquid metal outlet is connected with blender liquid metal entrance e, and the fluid-mixing of blender 7 is exported and the fluid-mixing of power channel 9 Entrance is connected, and the outlet of the fluid-mixing of power channel 9 is connected with the fluid-mixing entrance of separator 11, the liquid metal outlet of separator 11 G is connected with the liquid metal entrance c of heater 3.
Hot-water heating system includes condenser 12, cold water inlet pipe road 13 and hot water delivery pipe road 14.Wherein, the low boiling of separator 11 Point refrigerant vapor outlet h is connected with the low boiling working fluid vapour inlet i of condenser 12, the low boiling working fluid of condenser 12 outlet j and pump 10 low boiling working fluid entrances are connected, and the outlet of the low boiling working fluid of pump 10 is connected with the low boiling working fluid entrance f of blender 7, cold water input Pipeline 13 and the entrance k of condenser 12 are connected, and the outlet of condenser 12 l is connected with hot water delivery pipe road 14.Temperature controller 6 is used for prison in real time Liquid metal temperature in blender 7 is surveyed, when liquid metal temperature is less than its fusing point in blender 7, electric heater 8 is opened automatically Open, it is ensured that liquid metal temperature is higher than its fusing point without solidifying in blender 7.Above-mentioned each return external application insulation material Scattered and disappeared with reducing heat.
The course of work for the heat accumulating type metal magnetic fluid generating device of electric energy peak load shifting is:
The night of power plant 1 supplies electricity to electric heat accumulator 4, and the energy storage medium temperature in electric heat accumulator 4 is raised, and is converted electrical energy into Heat energy, electric heat accumulator is in the accumulation of energy stage;Daytime, electric heat accumulator 4 stopped accumulation of energy, and conduction oil is absorbed in the energy storage medium of electric heat accumulator 4 Heat, temperature reduction after heater 3 is passed to by pump 2, return to the heat that electric heat accumulator 4 absorbs in energy storage medium again, Electric heat accumulator is in the exoergic stage.
The heated temperature after heating of device 3 of liquid metal is raised, and is transported in blender 7 and low boiling by magnetic fluid pump 5 Working medium mixes, and due to directly contact, low boiling working fluid is vaporized, expanded quickly, accelerates to promote liquid metal flows, into MHD hairs After electric channel 9, fluid is that the liquid metal of flowing in two-phase mixture, passage produces resistance under magnetic fields, makes fluid pressure Power declines along passage, and gas expands under differential pressure, further promotes liquid metal flows cutting magnetic induction line to generate electricity, subsequently into point Carry out two-phase laminated flow from device 11, the liquid metal separated is heated by heater 3 through exporting g, after the pressurization of magnetic fluid pump 5 from Entrance e is again introduced into blender 7, and the low boiling working fluid steam separated is condensed into liquid through exporting h into condenser 12, Then pressurizeed by pump 8 and be again introduced into blender 5 from entrance f;For liquid metal does not solidify in ensureing blender 7, one is set The real-time monitoring liquid metal temperature of individual temperature controller 6, when liquid metal temperature is less than its fusing point, electric heater 8 is automatically turned on, plus Liquid metal in hot mixing device 7.
Cold water is raised from temperature after the condensed device 12 in cold water inlet pipe road 13 and high temperature low boiling working fluid heat exchange turns into heat Water, exports through hot water delivery pipe road 14, there is provided the unit of cold water and consumption hot water can be power plant, or residential quarters Etc. unit, if power plant, there is provided cold water can be high-temperature steam through the condensed condensed water of condenser, condensed water preheating temperature Degree sends into boiler after raising, it is possible to reduce water is heated into the fossil fuel that superheated steam is consumed by boiler;If residential quarters, The cold water of offer can be running water, and tap water heating temperature can be used as domestic hot-water after raising.
The regenerator temperature of current electric heat accumulator meets above hydromagnetic generating device to heat source temperature up to 1000K or so Demand.Magnetohydrodynamic generator mainly has two kinds of forms, high temperature plasma gas magnetohydrodynamic generator and liquid metal magnetohydrodynamic generation. To above-mentioned regenerator temperature 1000K, it is adapted to use liquid metal magnetohydrodynamic generation.After being heated in liquid metal magnetohydrodynamic generation system High temperature fluent metal enter blender and low boiling working fluid and mix, due to directly contact, low boiling working fluid is vaporized quickly, is promoted Liquid metal flows, into after MHD power channels, fluid is that the liquid metal of flowing in two-phase mixture, passage is made in magnetic field With lower generation resistance, Fluid pressure is set to decline along passage, metal gas expand under differential pressure, further promote liquid metal flows Cutting magnetic induction line generates electricity.
The present invention efficiently utilizes the unnecessary generated energy in night power plant, supplemented with power plant generated energy on daytime not Foot, not only takes full advantage of night unnecessary generated energy, it is thus also avoided that daytime, power plant was to meet user power utilization demand to high-carbon The consumption of the energy, realizes effect of the device to electric energy peak load shifting;And the device needs not move through mechanical switch link, directly Electric energy is converted heat energy into, design can be made simpler, reduce the cost of system, capacity usage ratio is higher.While this hair The bright heat accumulating type metal magnetic fluid generating device for electric energy peak load shifting realizes compact conformation, good economy performance, system The electric energy peak load shifting purpose of stabilization, is conducive to energy-saving and emission-reduction, low-carbon environment-friendly.
The above is only the preferred embodiment of the present invention, it is noted that for the ordinary skill people of the art For member, under the premise without departing from the principles of the invention, some improvements and modifications can also be made, these improvements and modifications also should It is considered as protection scope of the present invention.

Claims (2)

1. a kind of heat accumulating type metal magnetic fluid generating device for electric energy peak load shifting, it is characterised in that:Put including storing Hot systems, liquid metal magnetohydrodynamic generation system and hot-water heating system;
The storage thermal desorption system includes power plant (1), the first pump (2), heater (3) and electric heat accumulator (4);Electric heat accumulator (4) Conduction oil outlet is connected with the first pump (2) heat conduction oil-in, the first pump (2) conduction oil outlet and heater (3) heat conduction oil-in a Connection, heater (3) conduction oil outlet b is connected with electric heat accumulator (4) heat conduction oil-in;Power plant (1) night supplies electricity to Electric heat accumulator (4), electric heat accumulator on daytime (4) gives heater (3) by conduction oil heat supply;
The liquid metal magnetohydrodynamic generation system includes magnetic fluid pump (5), temperature controller (6), blender (7), electric heater (8), power channel (9), the second pump (10) and separator (11);Heater (3) the liquid metal outlet d and magnetic fluid pump (5) liquid metal entrance connection, magnetic fluid pump (5) liquid metal outlet is connected with blender liquid metal entrance e, blender (7) fluid-mixing outlet is connected with power channel (9) fluid-mixing entrance, and power channel (9) fluid-mixing is exported and separator (11) fluid-mixing entrance connection, separator (11) liquid metal outlet g is connected with heater (3) liquid metal entrance c;
The hot-water heating system includes condenser (12), cold water inlet pipe road (13) and hot water delivery pipe road (14);The separator (11) low boiling working fluid vapor outlet port h is connected with condenser (12) low boiling working fluid vapour inlet i, condenser (12) low boiling work Matter outlet j is connected with pump (10) low boiling working fluid entrance, and the outlet of pump (10) low boiling working fluid enters with blender (7) low boiling working fluid Mouth f connections, the cold water inlet pipe road (13) and condenser (12) entrance k are connected, condenser (12) outlet l and hot water delivery pipe Road (14) is connected;Temperature controller (6) for liquid metal temperature in real-time monitoring blender (7), when liquid metal in blender (7) When temperature is less than its fusing point, electric heater (8) is automatically turned on, it is ensured that liquid metal temperature is higher than its fusing point in blender (7) Do not solidify.
2. a kind of heat accumulating type liquid metal magnetohydrodynamic generation method for electric energy peak load shifting, it is characterised in that including as follows Step:
Step 1, power plant (1) night supplies electricity to electric heat accumulator (4), and the energy storage medium temperature of electric heat accumulator (4) is raised, by electric energy Heat energy is converted into, electric heat accumulator is in the accumulation of energy stage;
Step 2, electric heat accumulator on daytime (4) stops accumulation of energy, and the heat in electric heat accumulator (4) energy storage medium is absorbed by conduction oil, And heater (3) is passed to liquid metal heating by pump (2), the conduction oil after temperature reduction returns to electric heat accumulator (4) again The secondary heat absorbed in energy storage medium, electric heat accumulator is in the exoergic stage;
Step 3, liquid metal heated device (3) temperature after heating is raised, and is transported in blender (7) by magnetic fluid pump (5) Mix with low boiling working fluid, low boiling working fluid is vaporized and expands the dynamic liquid metal flows of pusher and enters MHD power channels (9), liquid State metal flow cutting magnetic induction line generates electricity;
Step 4, flow through the liquid metal after MHD power channels (9) carries out two-phase laminated flow into separator (11), separates The heated device of liquid metal (3) is heated, and is again introduced into blender (7), the low boiling separated after magnetic fluid pump (5) pressurization Point refrigerant vapor is condensed into liquid into condenser (12), and blender (5) is again introduced into after being then pressurized;One temperature control is set Liquid metal temperature in device (6) real-time monitoring blender (7), when liquid metal temperature is less than its fusing point, electric heater (8) is certainly It is dynamic to open, the liquid metal in heating mixer (7).
CN201710006847.4A 2017-01-05 2017-01-05 For the heat accumulating type metal magnetic fluid generating device and method of electric energy peak load shifting Pending CN106787601A (en)

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CN107221370A (en) * 2017-06-09 2017-09-29 南京航空航天大学 Core gradient utilization system and method based on liquid metal spontaneous evaporation magnetohydrodynamic generator
CN110534488A (en) * 2019-08-25 2019-12-03 大连理工大学 A kind of magnetic fluid pump installation and test method for IGBT heat dissipation
CN111007334A (en) * 2019-11-27 2020-04-14 山东大学 Experimental device for research on liquid metal magnetohydrodynamic power generation and using method thereof
CN113446081A (en) * 2021-08-11 2021-09-28 西安热工研究院有限公司 Liquid metal magnetofluid supercritical CO2Combined cycle power generation system and method
CN113644806A (en) * 2021-08-24 2021-11-12 南京航空航天大学 LMMHD power generation system based on flow type active regulation mechanism and working method
CN115863851A (en) * 2022-12-01 2023-03-28 西藏康盛能源开发有限公司 Energy storage device based on zinc sublimation and oxidation and control method thereof

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Publication number Priority date Publication date Assignee Title
CN107221370A (en) * 2017-06-09 2017-09-29 南京航空航天大学 Core gradient utilization system and method based on liquid metal spontaneous evaporation magnetohydrodynamic generator
CN110534488A (en) * 2019-08-25 2019-12-03 大连理工大学 A kind of magnetic fluid pump installation and test method for IGBT heat dissipation
CN110534488B (en) * 2019-08-25 2020-11-13 大连理工大学 Magnetic fluid pump device for IGBT heat dissipation and testing method
CN111007334A (en) * 2019-11-27 2020-04-14 山东大学 Experimental device for research on liquid metal magnetohydrodynamic power generation and using method thereof
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CN113644806A (en) * 2021-08-24 2021-11-12 南京航空航天大学 LMMHD power generation system based on flow type active regulation mechanism and working method
CN113644806B (en) * 2021-08-24 2022-06-17 南京航空航天大学 Working method of LMMHD power generation system based on flow pattern active regulation mechanism
CN115863851A (en) * 2022-12-01 2023-03-28 西藏康盛能源开发有限公司 Energy storage device based on zinc sublimation and oxidation and control method thereof
CN115863851B (en) * 2022-12-01 2023-10-10 茂炜能源股份有限公司 Energy storage device based on zinc sublimation and oxidation and control method thereof

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Application publication date: 20170531