CN1888005A - Prepn of heat accumulating for solar energy medium temperature steam electricity generation - Google Patents

Prepn of heat accumulating for solar energy medium temperature steam electricity generation Download PDF

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Publication number
CN1888005A
CN1888005A CNA2006100194784A CN200610019478A CN1888005A CN 1888005 A CN1888005 A CN 1888005A CN A2006100194784 A CNA2006100194784 A CN A2006100194784A CN 200610019478 A CN200610019478 A CN 200610019478A CN 1888005 A CN1888005 A CN 1888005A
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heat accumulating
slag
preparation
aggregate
electric power
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CN100494307C (en
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朱教群
周卫兵
吴少鹏
李波
王金山
张炳
汤凯
周明杰
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Hubei Kaijia Energy Technology Group Co. Ltd.
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Wuhan University of Technology WUT
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    • 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
    • Y02E10/00Energy generation through renewable energy sources
    • Y02E10/40Solar thermal energy, e.g. solar towers
    • Y02E10/46Conversion of thermal power into mechanical power, e.g. Rankine, Stirling or solar thermal engines
    • 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
    • Y02PCLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
    • Y02P80/00Climate change mitigation technologies for sector-wide applications
    • Y02P80/20Climate change mitigation technologies for sector-wide applications using renewable energy

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  • Curing Cements, Concrete, And Artificial Stone (AREA)

Abstract

The present invention is the preparation process of heat accumulating material for solar energy medium temperature steam electric power generation. The heat accumulating material is prepared with basalt and steel slag or copper slag as aggregate, fine silica powder, mineral slag powder, aluminate cement and nanometer level attapulgite, and through mixing while adding water, molding, demolding, curing in water for 72 hr and stoving at 100-120 deg.c for 24 hr. The heat accumulating material has high heat storing efficiency and heat releasing efficiency, and the preparation process can reduce industrial slag pollution.

Description

The warm steam-electric power preparation method of heat accumulating in a kind of sun power
Technical field
The present invention relates to the preparation of heat accumulating, particularly relate to the preparation method of warm steam-electric power usefulness heat accumulating in a kind of sun power.
Background technology
The heat accumulation conceptual design is the important technology in the solar steam generating, and the performance of heat accumulating and cost are one of the construction cost of decision large-sized solar power plant and principal element of running cost.The heat accumulating that is used for solar electrical energy generation should satisfy following requirement: heat accumulating should have high energy density; Heat accumulating and heat exchanger fluid should have good thermal conduction; Heat accumulating should have good chemistry and mechanical stability; Good chemical compatibility is arranged between heat accumulating and heat exchanger and the heat exchanger fluid; In heat accumulation and heat release working cycle, answer completely reversibility; Low-cost.
Mainly contain fused salt (KNO as the heat accumulating in the solar steam generating at present 3, NaNO 3Or both mixtures), iron ore.But fused salt exist one very obvious defects be its stronger corrodibility, heat exchanging pipe and other affiliated facility are had very strong corrosion behavior, increased the running cost of power plant thus, also reduced the security of system stability.Iron ore then owing to be loose stacking states, is unfavorable for heat accumulation and exothermic process, influences the efficient of system.The concrete heat accumulating is one of ideal candidates heat accumulating that is used for the solar steam generating owing to have plurality of advantages such as stable performance, cost is low, heat storage capacity is strong.Document (1) has been reported Japanese scholar's United States Patent (USP), is the heat accumulating that main raw material is formed with sodium sulfate, ammonium chloride, Sodium Bromide and ammonium sulfate wherein.The patent of document (2) has reported then and has been used for the solar energy heat-storage material that major ingredients is a sodium-chlor.Document (3-5) has been reported under the low temperature, at the fatty acid phase-change heat-storage material of building use.Document (6-7) has then been reported the phase-change heat-storage material of forming with paraffin and expanded graphite.But the heat accumulating of reporting in the above document, or be that cost is too high, or can only use under low temperature, and the heat accumulating of using as sun power must be considered the performance of its use under prerequisite cheaply.
Summary of the invention
Technical problem to be solved by this invention is: the preparation method that warm steam-electric power usefulness heat accumulating in a kind of sun power is provided, this method is set about from selection, composition and preparation technology to material are optimized design, thereby can produce a kind of novel solar power generation heat accumulating at low cost, the over-all properties of this material is greatly improved.
The technical solution adopted for the present invention to solve the technical problems is: comprise selection, batching and preparation process, it is an aggregate with basalt, slag or copper ashes, adding silicon powder, slag powders, aluminate cement and nanoscale Attapulgite micro mist is raw material, warm steam-electric power heat accumulating in the preparation sun power.
(1) raw material is formed and composition range:
Weight ratio and granularity that raw material is formed are: basalt aggregate 25~50%, granularity 10~30mm; Slag or copper ashes aggregate 20~38%, granularity 1~10mm; 500 order aluminate cements 3~10%; 500 order slag powders 5~20%; 500 order silicon powders 1~5%; Attapulgite 1~5%, granularity 100~500nm; Add high efficiency water reducing agent 0.2~1%.
(2) preparation: with above-mentioned raw materials through dried be mixed even after, add 4~6% water, remix is even, place the punching block mould then, the demoulding after 24 hours, under 20~25 ℃ of temperature, place the water maintenance 72 hours, under 100~120 ℃ of temperature, toasted 24 hours at last, promptly obtain warm steam-electric power heat accumulating in the described sun power.
Innovation part of the present invention is to adopt micropowder technology, utilize the reinforcing effect of nano particle simultaneously, adopt high efficiency water reducing agent and low-dosage aluminate cement as jointing compound, both significantly reduce the consumption (just having reduced the production energy consumption of raw material) and the mixing water amount of cement in the heat accumulating, significantly improved heat accumulating stability and work-ing life of (350~600 ℃) under working temperature again; Select that thermal capacitances such as slag, copper mine slag are big, thermal conductivity is higher for use, thermally-stabilised industrial residue preferably is as gathering materials, and not only solved the environmental pollution of industrial residue but also the volumetric heat capacity of modified concrete and thermal conductivity are improved significantly; Admixture natural attapulgite (Attopulgite) particle (there is ample resources in China Anhui Province), nanoscale attapulgite are filled in and improve concrete degree of compactness and intensity in the concrete mesoporosity; And, further improve heat accumulation, the exothermal efficiency of heat accumulating because attapulgite has performances such as excellent heat absorption, heat accumulation; Simultaneously according to heat transfer principle reasonable disposition steel wire grid and mix part graphite the thermal conductivity of new concrete heat accumulating is improved significantly; Select for use new and effective composite water-reducing agent to reduce the mixing water amount, improve workability of concrete and improve its degree of compactness and intensity.
Embodiment
The present invention relates to the preparation of novel solar power generation with heat accumulating, providing a kind of especially is aggregate with basalt, slag or copper ashes, adds silicon powder, slag powders, and aluminate cement, micro mists such as nanoscale Attapulgite prepare the method for heat accumulating.The working temperature of the heat accumulating of this method preparation can be at 600-900 ℃.
Embodiment 1
Weight ratio and granularity that raw material is formed are: basalt aggregate 38%, granularity 10~30mm; Slag aggregate 32%, granularity 1~10mm; 500 order aluminate cements 8%; 500 order slag powders 15%; 500 order silicon powders 5%; Attapulgite 2%, granularity 100~500nm; Add high efficiency water reducing agent 0.3%.
The industrial abandoned mine slag of the optional usefulness of slag powders in this example and following examples, its oven dry is milled down to 500 orders after, add in the material.Not only improved the flowability of mixing material, the later strength to the preparation material has bigger contribution simultaneously.
Raw material through dried be mixed even after, add 6% water, mix and be placed in the punching block mould, the demoulding after 24 hours, maintenance is after 72 hours in the water under 20-25 ℃ of temperature, baking is 24 hours under 100-120 ℃ of temperature.The density of heat accumulating is 2.98g/cm 3, on the omnipotent test machine for mechanism of INSTRON-1195, record, the ultimate compression strength 〉=50MPa of material, folding strength 〉=8MPa records volumetric heat capacity 145kWh/m on the comprehensive thermal analyzer 3, conductometer records thermal conductivity 1.75W/mK, 1000 ℃ of refractoriness.
Embodiment 2
Weight ratio and granularity that raw material is formed are: basalt aggregate 35%, granularity 10~30mm; Copper ashes aggregate 35%, granularity 1~10mm; 500 order aluminate cements 6%; 500 order slag powders 17%; 500 order silicon powders 4%; Attapulgite 3%, granularity 100~500nm; Add high efficiency water reducing agent 0.3%.
Raw material through prepare burden dried be mixed even after, add 5.5% water, mix and be placed in the punching block mould, the demoulding after 24 hours, maintenance is after 72 hours in the water under 20-25 ℃ of temperature, baking is 24 hours under 100-120 ℃ of temperature.The density of heat accumulating is 2.96g/cm 3, on the omnipotent test machine for mechanism of INSTRON-1195, record the ultimate compression strength 〉=60MPa of material, folding strength σ b 〉=12MPa, volumetric heat capacity 148kWh/m 3, thermal conductivity 1.77W/mK, 1000 ℃ of refractoriness.
Embodiment 3
Weight ratio and granularity that raw material is formed are: basalt aggregate 25%, granularity 10~30mm; Slag aggregate 38%, granularity 1~10mm; 500 order aluminate cements 10%; 500 order slag powders 20%; 500 order silicon powders 5%; Attapulgite 2%, granularity 100~500nm; High efficiency water reducing agent 0.3%.
Raw material through dried be mixed even after, add 6% water, mix and be placed in the punching block mould, the demoulding after 24 hours, maintenance is after 72 hours in the water under 20-25 ℃ of temperature, baking is 24 hours under 100-120 ℃ of temperature.The density of heat accumulating is 2.98g/cm 3, on the omnipotent test machine for mechanism of INSTRON-1195, record, the ultimate compression strength 〉=50MPa of material, folding strength 〉=8MPa records volumetric heat capacity 145kWh/m on the comprehensive thermal analyzer 3, conductometer records thermal conductivity 1.75W/mK, 1000 ℃ of refractoriness.
Embodiment 4
Weight ratio and granularity that raw material is formed are: basalt aggregate 50%, granularity 10~30mm; Copper ashes aggregate 20%, granularity 1~10mm; 500 order aluminate cements 10%; 500 order slag powders 11.7%; 500 order silicon powders 3%; Attapulgite 5%, granularity 100~500nm; High efficiency water reducing agent 0.3%.
Raw material through prepare burden dried be mixed even after, add 5.5% water, mix and be placed in the punching block mould, the demoulding after 24 hours, maintenance is after 72 hours in the water under 20-25 ℃ of temperature, baking is 24 hours under 100-120 ℃ of temperature.The density of heat accumulating is 2.96g/cm 3, on the omnipotent test machine for mechanism of INSTRON-1195, record the ultimate compression strength 〉=60MPa of material, folding strength σ b 〉=12MPa, volumetric heat capacity 148kWh/m 3, thermal conductivity 1.77W/mK, 1000 ℃ of refractoriness.
Embodiment 5
Weight ratio and granularity that raw material is formed are: basalt aggregate 38%, granularity 10~30mm; Copper ashes aggregate 38%, granularity 1~10mm; 500 order aluminate cements 8.7%; 500 order slag powders 5%; 500 order silicon powders 5%; Attapulgite 5%, granularity 100~500nm; High efficiency water reducing agent 0.3%.
Raw material through prepare burden dried be mixed even after, add 5.5% water, mix and be placed in the punching block mould, the demoulding after 24 hours, maintenance is after 72 hours in the water under 20-25 ℃ of temperature, baking is 24 hours under 100-120 ℃ of temperature.The density of heat accumulating is 2.96g/cm 3, on the omnipotent test machine for mechanism of INSTRON-1195, record the ultimate compression strength 〉=60MPa of material, folding strength σ b 〉=12MPa, volumetric heat capacity 148kWh/m 3, thermal conductivity 1.77W/mK, 1000 ℃ of refractoriness.
Embodiment 6
Weight ratio and granularity that raw material is formed are: basalt aggregate 40%, granularity 10~30mm; Slag aggregate 30%, granularity 1~10mm; 500 order aluminate cements 3%; 500 order slag powders 20%; 500 order silicon powders 1%; Attapulgite 5%, granularity 100~500nm; High efficiency water reducing agent 1%.
Raw material through dried be mixed even after, add 6% water, mix and be placed in the punching block mould, the demoulding after 24 hours, maintenance is after 72 hours in the water under 20-25 ℃ of temperature, baking is 24 hours under 100-120 ℃ of temperature.The density of heat accumulating is 2.98g/cm 3, on the omnipotent test machine for mechanism of INSTRON-1195, record, the ultimate compression strength 〉=50MPa of material, folding strength 〉=8MPa records volumetric heat capacity 145kWh/m on the comprehensive thermal analyzer 3, conductometer records thermal conductivity 1.75W/mK, 1000 ℃ of refractoriness.
Bibliography
[1]Kakiuchi;Hiroyuki;Oka;Masahiro,US?patent(No.5567346)
[2]Ross;Randy,US?patent(No.5685151)
[3]Kadir?Tuncbilek,Ahmet?Sari,Sefa?Tarhan?et?al.Lauric?and?palmitic?acidseutectic?mixture?as?latent?heat?storage?material?for?low?temperature?heatingapplications?Energy,2005,30(5):677-692
[4]Ahmet?Sari.Eutectic?mixtures?of?some?fatty?acids?for?latent?heat?storage:Thermal?properties?and?thermal?reliability?with?respect?to?thermal?cycling,EnergyConversion?and?Management,2006,47(9-10):1207-1221
[5]Atul?Sharma,Lee?Dong?Won,D?Buddhi?and?Jun?Un?Park.Numerical?heat?transferstudies?of?the?fatty?acids?for?different?heat?exchanger?materials?on?the?performanceof?a?latent?heat?storage?system?Renewable?Energy,2005,30(14):2179-2187
[6]Zhengguo?Zhang?and?Xiaoming?Fang.Study?on?paraffin/expanded?graphitecomposite?phase?change?thermal?energy?storage?material.Energy?Conversion?andManagement,2006,47(3):303-310
[7]V.Shatikian,G.Ziskind?and?R.Letan.Numerical?investigation?of?a?PCM-basedheat?sink?with?internal?fins.International?Journal?of?Heat?and?Mass?Transfer,2005,48(17):3689-3706

Claims (5)

  1. In the sun power warm steam-electric power with the preparation method of heat accumulating, comprise selection, batching and preparation process, it is characterized in that with basalt, slag or copper ashes be aggregate, adding silicon powder, slag powders, aluminate cement and nanoscale Attapulgite micro mist is raw material, warm steam-electric power heat accumulating in the preparation sun power
    (1) raw material is formed and composition range:
    Weight ratio and granularity that raw material is formed are: basalt aggregate 25~50%, granularity 10~30mm; Slag or copper ashes aggregate 20~38%, granularity 1~10mm; 500 order aluminate cements 3~10%; 500 order slag powders 5~20%; 500 order silicon powders 1~5%; Attapulgite 1~5%, granularity 100~500nm; Add high efficiency water reducing agent 0.2~1%.
    (2) preparation:
    With above-mentioned raw materials through dried be mixed even after, add 4~6% water, remix is even, place the punching block mould then, the demoulding after 24 hours, under 20~25 ℃ of temperature, place the water maintenance 72 hours, under 100~120 ℃ of temperature, toasted 24 hours at last, promptly obtain warm steam-electric power heat accumulating in the described sun power.
  2. 2. the warm steam-electric power preparation method of heat accumulating in the sun power according to claim 1, it is characterized in that the weight ratio that raw material is formed is: basalt aggregate 38%, slag aggregate 32%, aluminate cement 8%, slag powders 15%, silicon powder 5%, Attapulgite 2% adds high efficiency water reducing agent 0.3%.
  3. 3. the warm steam-electric power preparation method of heat accumulating in the sun power according to claim 1, it is characterized in that the weight ratio that raw material is formed is: basalt aggregate 35%, copper ashes aggregate 35%, aluminate cement 6%, slag powders 17%, silicon powder 4%, Attapulgite 3% adds high efficiency water reducing agent 0.3%.
  4. 4. according to the preparation method of warm steam-electric power in claim 1 or the 2 or 3 described sun power with heat accumulating, it is characterized in that: slag powders is selected industrial abandoned mine slag for use, its oven dry is milled down to 500 orders after, add in the material.
  5. 5. warm steam-electric power is characterized in that warm steam-electric power heat accumulating in the described sun power with the preparation method of heat accumulating in the sun power according to claim 1, and its technical parameter is: density 2.96g/cm 3, ultimate compression strength 〉=50MPa, folding strength 〉=8MPa, volumetric heat capacity 145kWh/m 3, thermal conductivity 1.75W/mK, 1000 ℃ of refractoriness.
CNB2006100194784A 2006-06-27 2006-06-27 Preparation of heat accumulating material for solar energy medium temperature steam electricity generation Expired - Fee Related CN100494307C (en)

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CN102322759A (en) * 2011-06-22 2012-01-18 武汉理工大学 Concrete heat storage device with low cost for solar energy air conditioner
CN101876487B (en) * 2009-11-10 2012-07-18 武汉理工大学 Method for manufacturing prefabricated concrete heat storage module for solar heat power generation
CN103833302A (en) * 2014-03-18 2014-06-04 武汉理工大学 Phase change material wrapped thermal storage concrete and preparation method thereof
CN104357020A (en) * 2014-11-28 2015-02-18 巴彦淖尔市卓越建筑材料有限公司 Nanometer modified inorganic room-temperature phase change heat storage material and preparation method thereof
CN104673192A (en) * 2013-11-29 2015-06-03 中广核太阳能开发有限公司 Heat storage material for solar high-temperature steam power generation and preparation method thereof
CN104671728A (en) * 2013-11-29 2015-06-03 中广核太阳能开发有限公司 Concrete heat storage material for solar moderate-temperature steam electric power generation and preparation method thereof
CN106556255A (en) * 2016-09-26 2017-04-05 西安建筑科技大学 A kind of heat-storing material, preparation method and applications
CN109503072A (en) * 2018-12-04 2019-03-22 上海中冶环境工程科技有限公司 Smelt the purposes and weight concrete of copper ashes
CN115073136A (en) * 2022-06-10 2022-09-20 武汉理工大学 High-steel-slag-content heat absorption and storage integrated ceramic and preparation method thereof

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CN1108280C (en) * 2000-09-18 2003-05-14 中国建筑材料科学研究院 High-activity fine steelslag powder as additive of concrete and process for preparing concrete
US6641658B1 (en) * 2002-07-03 2003-11-04 United States Gypsum Company Rapid setting cementitious composition
GB2410282B (en) * 2004-01-20 2009-10-28 Tarmac Ltd Water management system
CN1724444A (en) * 2005-06-15 2006-01-25 张现民 Light energy-saving thermal preservation building material and it procucing method

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CN101876487B (en) * 2009-11-10 2012-07-18 武汉理工大学 Method for manufacturing prefabricated concrete heat storage module for solar heat power generation
CN102322759A (en) * 2011-06-22 2012-01-18 武汉理工大学 Concrete heat storage device with low cost for solar energy air conditioner
CN104673192A (en) * 2013-11-29 2015-06-03 中广核太阳能开发有限公司 Heat storage material for solar high-temperature steam power generation and preparation method thereof
CN104671728A (en) * 2013-11-29 2015-06-03 中广核太阳能开发有限公司 Concrete heat storage material for solar moderate-temperature steam electric power generation and preparation method thereof
CN103833302A (en) * 2014-03-18 2014-06-04 武汉理工大学 Phase change material wrapped thermal storage concrete and preparation method thereof
CN103833302B (en) * 2014-03-18 2016-08-17 武汉理工大学 A kind of accumulation of heat concrete of coating phase-change materials and preparation method thereof
CN104357020A (en) * 2014-11-28 2015-02-18 巴彦淖尔市卓越建筑材料有限公司 Nanometer modified inorganic room-temperature phase change heat storage material and preparation method thereof
CN104357020B (en) * 2014-11-28 2017-08-25 巴彦淖尔市卓越建筑材料有限公司 A kind of nano modified inorganic room temperature phase-change heat accumulating and preparation method thereof
CN106556255A (en) * 2016-09-26 2017-04-05 西安建筑科技大学 A kind of heat-storing material, preparation method and applications
CN109503072A (en) * 2018-12-04 2019-03-22 上海中冶环境工程科技有限公司 Smelt the purposes and weight concrete of copper ashes
CN115073136A (en) * 2022-06-10 2022-09-20 武汉理工大学 High-steel-slag-content heat absorption and storage integrated ceramic and preparation method thereof

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