CN101045642A - Building thermal insulation material of and preparation method thereof high mixed industrial waste material - Google Patents
Building thermal insulation material of and preparation method thereof high mixed industrial waste material Download PDFInfo
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- CN101045642A CN101045642A CNA200710078449XA CN200710078449A CN101045642A CN 101045642 A CN101045642 A CN 101045642A CN A200710078449X A CNA200710078449X A CN A200710078449XA CN 200710078449 A CN200710078449 A CN 200710078449A CN 101045642 A CN101045642 A CN 101045642A
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- cement clinker
- industrial waste
- gelling material
- foam
- flyash
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- Y—GENERAL 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
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02W—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO WASTEWATER TREATMENT OR WASTE MANAGEMENT
- Y02W30/00—Technologies for solid waste management
- Y02W30/50—Reuse, recycling or recovery technologies
- Y02W30/91—Use of waste materials as fillers for mortars or concrete
Abstract
An insulating material for building is proportionally prepared from powdered coal ash foaming material, sodium lauryl benzosulfonate, triethanolamine, cementing material and water. Its preparing process is also disclosed.
Description
Technical field
The present invention relates to a kind of material of construction, relating in particular to a kind of is thermal insulation building material of forming of material preparation and preparation method thereof with flyash and ordinary portland cement clinker mainly.
Background technology
The heat preserving and insulating material that uses in the building is various in style, use therein the most general heat preserving and insulating material, and inorganic materials has pearlstone, gas concrete, the rock silk floss, glass wool etc., organic materials has polystyrene foamed plastics, urethane foam etc.In the above-mentioned heat preserving and insulating material commonly used, pearlstone, rock silk floss, glass wool, the alkene porous plastics of polystyrene, the thermal conductivity of materials such as urethane foam is all smaller, though height also has difference, but differ not very very big, all belong to the thermal insulation material, but do not have weight-bearing function.And the polystyrene foamed plastics class is in construction, and during as exterior-wall heat insulation, what have fixes with the reinforcing bar keel, the outer cover woven wire, and then plaster, cause heat bridge to produce easily.Or with special binders and coupler sheet material is bonded on the exterior wall, after handling through some procedures again, just can reach technical requirements, it is very complicated to construct.It is very difficult that organic materials combines with brick wall, has carelessness will cause hollowing, come off and bring accident potential in the construction slightly.And the foam plastic product resistance of aging is poor, and rejected material can not be degraded and be caused " white pollution " about 20 years work-ing life.The resistance toheat of organic class heat preserving and insulating material is also bad.When fire takes place, melt easily, have the secondary potential safety hazard.
Pearlstone and goods rate of moisture absorption reduced water absorption are big, during apparent density 80-300kg/m3, and rate of moisture absorption 0.006%-0.080%, and also the more little suction of the more little rate of moisture absorption of apparent density is high.In putting into practice engineering.Adiabator layer often loses the heat insulating energy because of water-absorbent causes the performance increase of leading of thermal insulation layer greatly.Rock wool, mineral wool, glass wool are because of wherein containing pitch, glue or other organism in various degree, be easy to generate objectionable impurities and contaminate environment, simultaneously, because of its intensity low, easily subside and the production and processing technology complexity during as the heat insulating layer of building enclosure, replaced by other materials gradually.
Gas concrete sheet material has good body of wall adhesiveproperties as inorganic plate, and construction technology is simple.The volume of flyash is mainly at 20%-30% in the at present common gas concrete, and volume also is not very high.And ultimate compression strength is lower under low unit weight.
Summary of the invention
Technical problem to be solved by this invention is to overcome the deficiencies in the prior art, and a kind of novel high mixed industrial waste building heat preservation lagging material that excellent thermal and insulating performance reaches the high volume of industrial waste simultaneously that has is provided; Another object of the present invention provides the method for the described novel high mixed industrial waste building heat preservation lagging material of preparation
For realizing that the technical scheme that first purpose of the present invention adopts is such, promptly a kind of novel high mixed industrial waste building heat preservation lagging material is made of gelling material and foam materials mixing, wherein: every cubic metre of (m of foam material
3) moisture 5.4~5.5 liters, 0.9~0.95 kilogram of Sodium dodecylbenzene sulfonate, 0.9~0.95 kilogram of trolamine; Every cubic metre of foam material mixes with the gelling material of (150~450) kilogram and the water of 0.3~0.45 times of gelling material; Gelling material comprises cement clinker, flyash, vitriol and white lime, and the weight percent between them is ordinary portland cement clinker 20~40%, flyash 50~70%, vitriol 4~8% and white lime 2~6%; Or gelling material comprises cement clinker, flyash, vitriol, and the weight percent between them is ordinary portland cement clinker 25~45%, flyash 50~70%, vitriol 4~8%.
Above-mentioned flyash is mainly second class powered coal ash, also available first level flour coal ash.
Above-mentioned vitriol is selected from a kind of in sodium sulfate, vitriolate of tartar, sal epsom, the Tai-Ace S 150.
Above-mentioned cement clinker is selected from a kind of in ordinary portland cement clinker, Portland clinker, the sulphoaluminate cement clinker.
The technical scheme that adopts for realization the present invention second purpose is such, promptly a kind of method for preparing above-mentioned novel high mixed industrial waste building heat preservation lagging material, and it is characterized in that: method comprises following step:
1). starting material preparation and stirring:
Good according to proportioning required gelling material weighing, be placed on to stir in the mixing drum and made dry powder blend even in 2~4 two minutes, prevent that the cement clinker hydration rate is too fast.Add water toward the tube the inside then, stir with the blade stirring-head, the colloidal gelling material must flow; Sodium dodecylbenzene sulfonate, trolamine are measured in proportion, be placed on and be with in the graduated foaming tube, stir with the twayblade stirring-head after adding the water of respective amount then, stirs 3~5 minutes up to foaming fully;
2). mix bubble and injection molding
Gelling material and foam material are added continuation stirring in the quantitative foam cartridge, and churning time is 4~5 minutes, and direct then reverse mould is scraped plane surface with flat cutter, and under humidity 80%~90% condition, normal temperature leaves standstill the demoulding after 24 hours;
3). steam press maintenance
Knock-outs will after step 2 demoulding is inserted earlier in the autoclave, and steam press maintenance is 1~4 hour under 1.2~1.5 standard atmospheric pressures, vexed the supporting 1 hour of flame-out then continuation steam; The steam of control in the autoclave is slowly discharged, treat that vapor pressure drops to clean atmosphere pressure, temperature and drops to normal temperature after, promptly get product.
The inorganic heat insulation material that the present invention utilizes flyash to make for main component, its volume to weight ratio is generally at 250-600Kg/m
3, its weight is 1/5 of solid brick, 1/7 of normal concrete.Thermal resistance coefficient ren is between 0.060-0.135, and heat-proof quality is up to state standards.Have good acoustical absorptivity, the ultimate compression strength of its maintenance fortnight is greater than 1Mpa, and folding strength is that water-intake rate is between 8-22% between the 0.35-0.6.This material has good processability, can be processed into goods such as building block, wallboard, roof boarding, ground heating floor, heat insulating piece, and be widely used in industry and covil construction, as the heat preserving and insulating material of non-load bearing wall, becomes building material.
The present invention has been owing to utilized second class powered coal ash, and its volume reaches 50-70%, not only turn waste into wealth, and required cement class gelling material obviously reduces.Utilize ordinary Portland cement to replace aluminosulfate cement (high-strength cement), make and reduce such inorganic heat insulation material and be subjected to that special cement is regional to be influenced, make height mix the industrial waste lagging material and obtain higher generalization in the whole nation.The present invention does not have the secondary white pollution problems of organic class lagging material for the comprehensive utilization of flyash has proposed new method.
Description of drawings
Fig. 1 is the aperture comparison diagram; Being the material by embodiment 1 preparation above, is the lagging material that Mianyang, Sichuan timely rain company produces below.Can see that by contrast the aperture ratio contrast material aperture of product of the present invention is little;
Fig. 2 is preparation flow figure of the present invention; Utilize this schema just can realize that the present invention is in application in engineering;
Fig. 3 is the influence comparison diagram of later stage maintenance method to intensity; Can get by contrast, use normal temperature wet foster best the development impact of intensity to three kinds of different later stage maintenance methods.
Fig. 4 is the development figure of intensity with curing time; By 3 days, 7 days, 14 days, 28 days intensity of test material of the present invention, material can use in the time of 14 days as can be seen, but along with the strength development of the increase material of the present invention of curing time is very fast.
Fig. 5 is the influence comparison diagram of steam-cured time to intensity; Material of the present invention was placed under 1.2~1.5 standard atmospheric pressures steam press maintenance 1~4 hour, flame-outly then continues that steam is vexed supported 1 hour; Test its seven days intensity.Take all factors into consideration intensity and economy, figure steam press maintenance 1 hour under 1.2~1.5 standard atmospheric pressures as can be seen again, it is flame-out then that to continue the vexed vapor cure mode of supporting 1 hour of steam be optimum;
Fig. 6 is the thermal resistance coefficient comparison diagram; Utilize the conduction temperature variations of home-made contrivance test material of the present invention and contrast material, will get well from the heat-proof quality that this figure can material of the present invention.
Embodiment
Further describe the present invention by the following examples, it should be understood that these embodiment only are used for the purpose of illustration, never limit the scope of the invention.
The preparation (containing white lime) of embodiment 1 lagging material of the present invention
Take by weighing each raw material (unit: Kg): second class powered coal ash 60, ordinary portland cement clinker (dry production) 30, sodium sulfate 6, lime 4 by following weight.After above-mentioned starting material being mixed the water of 0.4 times of weight of back adding, after stirring 5 minutes under 200 rotating speeds, obtain the gelling material slurry.Then with taking the standard foam 0.3m that top standard method prepares
3, the gelling material slurry for preparing is previously poured in the standard foam, after stirring 4 minutes under 200 rotating speeds, inject mould molding.The maintenance demoulding in 24 hours under the 80%-90% humidity condition.Steam press maintenance 1 hour under 1.2~1.5 standard atmospheric pressures more flame-outly then continues that steam is vexed supported 1 hour; Can obtain lagging material of the present invention in maintenance under the 80%-90% humidity condition after 14 days.
The prepared lagging material of present embodiment detects through our lab investigation center, and its every detected result sees Table 2.
Table 2: every Performance Detection index of lagging material of the present invention
Test item | Standard index | Test value | Individual event is judged |
Wet apparent density (kg/m 3) dried apparent density (kg/m 3) thermal conductivity [W/ (m.K)] ultimate compression strength (MPa) | ≤530 ≤420 ≤0.100 ≥0.6 | 470 405 0.070 1.1 | Qualified qualified excellence |
Linear shrinkage (%) | ≤0.2 | 0.15 | Qualified |
The preparation of embodiment 2 lagging materials of the present invention (no white lime)
Take by weighing each raw material (unit: Kg): second class powered coal ash 62, ordinary portland cement clinker (dry production) 32, sodium sulfate 6 by following weight.After above-mentioned starting material being mixed the water of 0.4 times of weight of back adding, after stirring 5 minutes under 200 rotating speeds, obtain the gelling material slurry.Then with taking the standard foam 0.3m that top standard method prepares
3, the gelling material slurry for preparing is previously poured in the standard foam, after stirring 4 minutes under 200 rotating speeds, inject mould molding.The maintenance demoulding in 24 hours under the 80%-90% humidity condition.Steam press maintenance 1 hour under 1.2~1.5 standard atmospheric pressures more flame-outly then continues that steam is vexed supported 1 hour; Can obtain lagging material of the present invention in maintenance under the 80%-90% humidity condition after 14 days.
The prepared lagging material of present embodiment detects through our lab investigation center, and its every detected result sees Table 3.
Table 3: every Performance Detection index of lagging material of the present invention
Test item | Standard index | Test value | Individual event is judged |
Wet apparent density (kg/m 3) dried apparent density (kg/m 3) thermal conductivity [W/ (m.K)] ultimate compression strength (MPa) | ≤530 ≤420 ≤0.100 ≥0.6 | 468 401 0.072 1.05 | Qualified qualified excellence |
Linear shrinkage (%) | ≤0.2 | 0.13 | Qualified |
The preparation of embodiment 3 lagging materials of the present invention (second class powered coal ash 50% volume)
Take by weighing each raw material (unit: Kg): second class powered coal ash 50, ordinary portland cement clinker (dry production) 40, sodium sulfate 4, lime 6 by following weight.After above-mentioned starting material being mixed the water of 0.4 times of weight of back adding, after stirring 5 minutes under 200 rotating speeds, obtain the gelling material slurry.Then with taking the standard foam 0.3m that top standard method prepares
3, the gelling material slurry for preparing is previously poured in the standard foam, after stirring 4 minutes under 200 rotating speeds, inject mould molding.The maintenance demoulding in 24 hours under the 80%-90% humidity condition.Steam press maintenance 1 hour under 1.2~1.5 standard atmospheric pressures more flame-outly then continues that steam is vexed supported 1 hour.Can obtain lagging material of the present invention in maintenance under the 80%-90% humidity condition after 14 days.
The prepared lagging material of present embodiment detects through our lab investigation center, and its every detected result sees Table 4.
Table 4: every Performance Detection index of lagging material of the present invention
Test item | Standard index | Test value | Individual event is judged |
Wet apparent density (kg/m 3) dried apparent density (kg/m 3) thermal conductivity [W/ (m.K)] ultimate compression strength (MPa) | ≤530 ≤420 ≤0.100 ≥0.6 | 473 408 0.075 1.15 | Qualified qualified excellence |
Linear shrinkage (%) | ≤0.2 | 0.16 | Qualified |
The preparation (sulphoaluminate cement clinker) of embodiment 4 lagging materials of the present invention
Take by weighing each raw material (unit: Kg): second class powered coal ash 60, sulphoaluminate cement clinker (dry production) 30, sodium sulfate 6, lime 4 by following weight.After above-mentioned starting material being mixed the water of 0.4 times of weight of back adding, after stirring 5 minutes under 200 rotating speeds, obtain the gelling material slurry.Then with taking the standard foam 0.3m that top standard method prepares
3, the gelling material slurry for preparing is previously poured in the standard foam, after stirring 4 minutes under 200 rotating speeds, inject mould molding.The maintenance demoulding in 24 hours under the 80%-90% humidity condition.Steam press maintenance 1 hour under 1.2~1.5 standard atmospheric pressures more flame-outly then continues that steam is vexed supported 1 hour.Can obtain lagging material of the present invention in maintenance under the 80%-90% humidity condition after 14 days.
The prepared lagging material of present embodiment detects through our lab investigation center, and its every detected result sees Table 5.
Table 5: every Performance Detection index of lagging material of the present invention
Test item | Standard index | Test value | Individual event is judged |
Wet apparent density (kg/m 3) dried apparent density (kg/m 3) thermal conductivity [W/ (m.K)] ultimate compression strength (MPa) | ≤530 ≤420 ≤0.100 ≥0.6 | 465 401 0.067 1.04 | Qualified qualified excellence |
Linear shrinkage (%) | ≤0.2 | 0.16 | Qualified |
The preparation of embodiment 5 lagging materials of the present invention (using vitriolate of tartar to excite)
Take by weighing each raw material (unit: Kg): second class powered coal ash 60, ordinary portland cement clinker (dry production) 30, vitriolate of tartar 6, lime 4 by following weight.After above-mentioned starting material being mixed the water of 0.4 times of weight of back adding, after stirring 5 minutes under 200 rotating speeds, obtain the gelling material slurry.Then with taking the standard foam 0.3m that top standard method prepares
3, the gelling material slurry for preparing is previously poured in the standard foam, after stirring 4 minutes under 200 rotating speeds, inject mould molding.The maintenance demoulding in 24 hours under the 80%-90% humidity condition.Steam press maintenance 1 hour under 1.2~1.5 standard atmospheric pressures more flame-outly then continues that steam is vexed supported 1 hour.Can obtain lagging material of the present invention in maintenance under the 80%-90% humidity condition after 14 days.
The prepared lagging material of present embodiment detects through our lab investigation center, and its every detected result sees Table 6.
Table 6: every Performance Detection index of lagging material of the present invention
Test item | Standard index | Test value | Individual event is judged |
Wet apparent density (kg/m 3) dried apparent density (kg/m 3) thermal conductivity [W/ (m.K)] ultimate compression strength (MPa) | ≤530 ≤420 ≤0.100 ≥0.6 | 470 403 0.067 1.12 | Qualified qualified excellence |
Linear shrinkage (%) | ≤0.2 | 0.12 | Qualified |
The preparation of embodiment 6 lagging materials of the present invention (using the first level flour coal ash)
Take by weighing each raw material (unit: Kg): first level flour coal ash 60, ordinary portland cement clinker (dry production) 30, vitriolate of tartar 6, lime 4 by following weight.After above-mentioned starting material being mixed the water of 0.4 times of weight of back adding, after stirring 5 minutes under 200 rotating speeds, obtain the gelling material slurry.Then with taking the standard foam 0.3m that top standard method prepares
3, the gelling material slurry for preparing is previously poured in the standard foam, after stirring 4 minutes under 200 rotating speeds, inject mould molding.The maintenance demoulding in 24 hours under the 80%-90% humidity condition.Steam press maintenance 1 hour under 1.2~1.5 standard atmospheric pressures more flame-outly then continues that steam is vexed supported 1 hour.Can obtain lagging material of the present invention in maintenance under the 80%-90% humidity condition after 14 days.
The prepared lagging material of present embodiment detects through our lab investigation center, and its every detected result sees Table 7.
Table 7: every Performance Detection index of lagging material of the present invention
Test item | Standard index | Test value | Individual event is judged |
Wet apparent density (kg/m 3) dried apparent density (kg/m 3) thermal conductivity [W/ (m.K)] ultimate compression strength (MPa) | ≤530 ≤420 ≤0.100 ≥0.6 | 460 400 0.065 1.34 | Qualified qualified excellence |
Linear shrinkage (%) | ≤0.2 | 0.11 | Qualified |
The preparation of embodiment 7 lagging materials of the present invention (second class powered coal ash 70% volume)
Take by weighing each raw material (unit: Kg): first level flour coal ash 70, ordinary portland cement clinker (dry production) 20, sodium sulfate 6, lime 4 by following weight.After above-mentioned starting material being mixed the water of 0.4 times of weight of back adding, after stirring 5 minutes under 200 rotating speeds, obtain the gelling material slurry.Then with taking the standard foam 0.3m that top standard method prepares
3, the gelling material slurry for preparing is previously poured in the standard foam, after stirring 4 minutes under 200 rotating speeds, inject mould molding.The maintenance demoulding in 24 hours under the 80%-90% humidity condition.Use " 1+1 " vapor cure again.Can obtain lagging material of the present invention in maintenance under the 80%-90% humidity condition after 14 days.
The prepared lagging material of present embodiment detects through our lab investigation center, and its every detected result sees Table 8.
Table 8: every Performance Detection index of lagging material of the present invention
Test item | Standard index | Test value | Individual event is judged |
Wet apparent density (kg/m 3) dried apparent density (kg/m 3) thermal conductivity [W/ (m.K)] ultimate compression strength (MPa) | ≤530 ≤420 ≤0.100 ≥0.6 | 474 404 0.075 1.00 | Qualified qualified excellence |
Linear shrinkage (%) | ≤0.2 | 0.17 | Qualified |
The effect test of embodiment 8 lagging materials of the present invention
One, test materials: the lagging material that the embodiment of the invention 1 is prepared
Two, test site: ChongQing, Chongqing City university of communications
Three, test method and result
Test room and contrast room are set.The test room uses lagging material of the present invention in manufacture process, the contrast room in manufacture process except that not using any lagging material, other and any construction and with material all with to test the room identical.
The test room uses the method for lagging material of the present invention as follows in manufacture process:
1) on the blank wall, at first is coated with the last layer screed-coat; 2) be 0.4 grout thickness with water-cement ratio be that the lagging material of the present invention of 30mm pastes the screed-coat surface; 3) on thermal insulation layer of the present invention, be coated with anticracking mortar 4 again) pacify one deck alkali proof fiber net again on anticracking mortar surface; 5) at the online face of the alkali proof fiber mortar of cementing again; 6) be coated with flexible putty on the surface at last.
(do not turn on the aircondition in test room and contrast room after testing in hot period, all be in the unoccupied state of nature, all door and window closes, detected the room temp in test room and contrast room in continuous 10 days), detected result is that the room temp in test room will be compared according to the room temp in room and on average will hang down 5-8 degree centigrade.Test-results shows that lagging material of the present invention has excellent heat-insulating property.
Claims (5)
1, a kind of novel high mixed industrial waste building heat preservation lagging material is made of gelling material and foam materials mixing, wherein: every cubic metre of (m of foam material
3) moisture 5.4~5.5 liters, 0.9~0.95 kilogram of Sodium dodecylbenzene sulfonate, 0.9~0.95 kilogram of trolamine; Every cubic metre of foam material mixes with the gelling material of (150~450) kilogram and the water of 0.3~0.45 times of gelling material weight; Gelling material comprises cement clinker, flyash, vitriol and white lime, and the weight percent between them is ordinary portland cement clinker 20~40%, flyash 50~70%, vitriol 4~8% and white lime 2~6%; Or gelling material comprises cement clinker, flyash, vitriol, and the weight percent between them is ordinary portland cement clinker 25~45%, flyash 50~70%, vitriol 4~8%.
2, novel high mixed industrial waste building heat preservation lagging material as claimed in claim 1, it is characterized in that: described flyash is mainly second class powered coal ash, also available first level flour coal ash.
3, novel high mixed industrial waste building heat preservation lagging material as claimed in claim 1 is characterized in that: vitriol is selected from a kind of in sodium sulfate, vitriolate of tartar, sal epsom, the Tai-Ace S 150.
4, novel high mixed industrial waste building heat preservation lagging material as claimed in claim 1 is characterized in that: cement clinker is selected from a kind of in ordinary portland cement clinker, Portland clinker, the sulphoaluminate cement clinker.
5, the method for the novel according to claim 1 high mixed industrial waste building heat preservation of a kind of preparation lagging material, it is characterized in that: method comprises step:
1). starting material preparation and stirring:
Good according to proportioning required gelling material weighing, be placed on to stir in the mixing drum and made dry powder blend even in 2~4 two minutes, prevent that the cement clinker hydration rate is too fast.Add water toward the tube the inside then, stir with the blade stirring-head, the colloidal gelling material must flow; Sodium dodecylbenzene sulfonate, trolamine are measured in proportion, be placed on and be with in the graduated foaming tube, stir with the twayblade stirring-head after adding the water of respective amount then, stirs 3~5 minutes up to foaming fully;
2). mix bubble and injection molding
Gelling material and foam material are added continuation stirring in the quantitative foam cartridge, and churning time is 4~5 minutes, and direct then reverse mould is scraped plane surface with flat cutter, and under humidity 80%~90% condition, normal temperature leaves standstill the demoulding after 24 hours;
3). steam press maintenance
Knock-outs will after step 2 demoulding is inserted earlier in the autoclave, and steam press maintenance is 1~4 hour under 1.2~1.5 standard atmospheric pressures, vexed the supporting 1 hour of flame-out then continuation steam; The steam of control in the autoclave is slowly discharged, treat that vapor pressure drops to clean atmosphere pressure, temperature and drops to normal temperature after, promptly get product.
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CN102633521A (en) * | 2012-03-26 | 2012-08-15 | 鞍山全益居环保建材有限公司 | Inorganic ultra-light cement foamed fireproof insulation board and preparation method for same |
CN101434475B (en) * | 2007-11-14 | 2012-08-29 | 瑞景投资控股有限公司 | Light floamed ceramic building board and preparation thereof |
CN102803178A (en) * | 2010-03-04 | 2012-11-28 | 格奥吕特矿产技术有限公司 | Mineral foam |
CN103981946A (en) * | 2014-05-08 | 2014-08-13 | 吕爱萍 | Manufacturing method of simple heat preservation stack cover plate |
CN106116444A (en) * | 2016-06-27 | 2016-11-16 | 石鸿娟 | A kind of thermal insulation building material based on waste residue and preparation method thereof |
CN106242394A (en) * | 2016-07-25 | 2016-12-21 | 广西云吉环保科技有限公司 | A kind of method utilizing blast-furnace cinder to produce insulation stripping and slicing for building |
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Publication number | Priority date | Publication date | Assignee | Title |
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CN101434475B (en) * | 2007-11-14 | 2012-08-29 | 瑞景投资控股有限公司 | Light floamed ceramic building board and preparation thereof |
CN102803178A (en) * | 2010-03-04 | 2012-11-28 | 格奥吕特矿产技术有限公司 | Mineral foam |
CN102633521A (en) * | 2012-03-26 | 2012-08-15 | 鞍山全益居环保建材有限公司 | Inorganic ultra-light cement foamed fireproof insulation board and preparation method for same |
CN103981946A (en) * | 2014-05-08 | 2014-08-13 | 吕爱萍 | Manufacturing method of simple heat preservation stack cover plate |
CN106116444A (en) * | 2016-06-27 | 2016-11-16 | 石鸿娟 | A kind of thermal insulation building material based on waste residue and preparation method thereof |
CN106242394A (en) * | 2016-07-25 | 2016-12-21 | 广西云吉环保科技有限公司 | A kind of method utilizing blast-furnace cinder to produce insulation stripping and slicing for building |
CN115462285A (en) * | 2021-09-28 | 2022-12-13 | 重庆交通大学 | Pressing device and method for preparing plant-growing foam building blocks |
CN115462285B (en) * | 2021-09-28 | 2024-03-01 | 重庆交通大学 | Pressing device and preparation method for preparation of plant-growing foam building blocks |
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