CN104120893A - 新能源智能保温楼 - Google Patents
新能源智能保温楼 Download PDFInfo
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- CN104120893A CN104120893A CN201410331817.7A CN201410331817A CN104120893A CN 104120893 A CN104120893 A CN 104120893A CN 201410331817 A CN201410331817 A CN 201410331817A CN 104120893 A CN104120893 A CN 104120893A
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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
- Y02B—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
- Y02B10/00—Integration of renewable energy sources in buildings
- Y02B10/20—Solar thermal
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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
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E10/00—Energy generation through renewable energy sources
- Y02E10/40—Solar thermal energy, e.g. solar towers
- Y02E10/44—Heat exchange systems
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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
- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
- Y02P80/00—Climate change mitigation technologies for sector-wide applications
- Y02P80/20—Climate change mitigation technologies for sector-wide applications using renewable energy
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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
- Y02W10/00—Technologies for wastewater treatment
- Y02W10/30—Wastewater or sewage treatment systems using renewable energies
- Y02W10/37—Wastewater or sewage treatment systems using renewable energies using solar energy
Abstract
新能源智能保温楼的主要优点:使人类告别了一次性能源、石油、煤炭、天然气为热源的冬季取暖法,节约了以电能为能源的夏季降温制冷法,实现了冬季取暖夏季降温制冷污染零排放,生活污水微生物分解处理达标排放,一次性投入,终生受益,节能省钱,冬暖夏凉,实现地下给水、排水、强电、弱点、供热、制冷等地下隧洞网络传输传导综合利用,结合人防工程,多行业联合施工,减少了有关行业的重复建设,节约了土地和资金,拉动多个行业的进步和创新,提高人类居住环境质量,有利人的身心健康,提高人体免疫力,提高健康水平,节约医疗费用,减轻病痛之苦,有利人体与自然界四季变化相适应,相融合,缩小人体与自然界变化过程中的温差效应。
Description
一、原理:新能源智能保温楼是利用太阳光照可转变成电能,热能的互变性、空气热胀冷缩的运动动力传导性和地球运行动能,热容性及特种微生物的分解转化性,经过科学技术施工巧妙的结合在一起,实现为人类服务
二、主要优点:新能源智能保温楼,使人类告别了一次性能源、石油、煤炭、天然气为热源的冬季取暖法,节约了以电能为能源的夏季降温制冷法,实现了冬季取暖夏季降温制冷污染零排放,生活污水微生物分解处理达标排放,一次性投入,终生受益,节能省钱,冬暖夏凉,实现地下给水、排水、强电、弱点、供热、制冷等地下隧洞网络传输传导综合利用,结合人防工程,多行业联合施工,减少了有关行业的重复建设,节约了土地和资金,拉动多个行业的进步和创新,提高人类居住环境质量,有利人的身心健康,提高人体免疫力,提高健康水平,节约医疗费用,减轻病痛之苦,有利人体与自然界四季变化相适应,相融合,缩小人体与自然界变化过程中的温差效应,实现人居生活生态化,人居生活理念个性化,人居生活规律自然化,有利于人与动、植物的和谐发展与生栖,是拉动国民经济增长的新亮点,对现有楼房进行改造。
三、适宜区域:有人类长期居住的地方。
四、技术要点:新能源智能保温楼主要由空气过滤小房1、空气过滤管2、通道3、微隧洞4、空压风机5、管网制冷恒温系统6、多功能综合隧洞7、进气管8、强电9、弱电10、进水管11、进气分户管箍12、排水管13、涡扇风电系统14、综合风洞15、排气风户管箍16、空压阀室内环境控制器17、排气管18、网络传输报警系统19、漏斗20、安全护栏21、内置推拉式增温系统22、折叠式光伏系统23、外置增温系统24、保温玻璃窗25、墙体保温26和楼房主体组成,如图1;生活污水微生物净化系统主要由防渗漏层、保温层、微生物特种种群、污水池、污水进口、排污泵、空压风机、管网、太阳光热增温系统、溢流口、沼气收集利用系统、密封盖等组成;保温玻璃窗是由特制的孔式模具、把融化的金属或非金属经过拉挤成型技术工艺制造成多根肋骨圆弧式T型产品,如图2;多根肋骨圆弧式J型产品,如图3;C型扣槽边缘向外翻折成弧型产品,如图4;∠型扣槽边缘向外翻折成圆弧型产品,如图5;并用连接配件相连接,经过技术工艺加工,制作成多层式保温玻璃窗,玻璃间距主要有相等间距法,如图6;大小间距法如图7;太阳光热玻璃管主要由透光率高的玻璃或钢化玻璃制成圆筒型玻璃管,再把制好的半圆瓦垄式圆筒型太阳光热板插入圆筒型玻璃管内,如图8;是一只直筒型光热玻璃管,或把透光率高的玻璃或钢化玻璃经过吹制或模制工艺技术,首先制造一只圆筒型小直径玻璃直管,直管一端连接带有边缘向外测翻折的环形托盘,托盘上制作有一抽气小孔插入一只透光率高的圆筒型大直径玻璃直管一端连接带有边缘向内侧翻折的环形托盘的直管内,进行熔焊,通过小管把隔层内的空气抽出,再把小管融化,然后再把制好的半圆瓦垄圆筒型光热板插入保温直筒型玻璃管内,如图9;是一只直筒型保温光热玻璃管;通过滚模压制技术工艺系统把金属或非金属板压制成半圆瓦垄型或半球型板,涂上太阳光热涂料,制成半圆瓦垄型如图10.或半球型如图11是两种太阳能光热板;内置增温系统:主要有推拉折叠式太阳光热板系统如图12或窗帘式两种;外置增温系统主要有多通多孔保温管网式如图13或多通集热箱式如图14或集热墙式三种;空压过滤房是由柱、门、顶和百叶墙体如图15组成;多通式分户管箍是由多通式管箍和舌组成如图16;多通多舌式空压阀主要由多通多舌阀体,舌道,同心轴舌体,转柄,同心轴,封闭盖等组成如图17;管网制冷恒温系统分为单层式和多层式两种,单层式管网制冷恒温系统是把隧洞用管道并联在一起如图18;多功能综合隧洞主要功能是给水系统、排水系统、强电系统、弱电系统、信息监控系统、制冷恒温系统的综合传输如图19。
五、示范推广。
六、附图说明:图1是新能源智能保温楼简图。图2是多肋骨圆弧式T型产品图。图3是多肋骨圆弧式J型产品图。图4是边缘向外翻折成圆弧式C型扣槽图。图5是边缘向外翻折成圆弧式∠型扣槽图。图6是多层相等间距保温玻璃窗。图7是大小间距多层玻璃保温窗。图8是直筒型光热玻璃管。图9是直筒型光热型保温玻璃管。图10是半圆瓦垄式太阳光热板。图11是半球式太阳光热板。图12是内置推拉折叠式太阳光热增温系统。图13是外置多通保温管网式增温系统。图14是多通集热厢式增温系统。图15是空气过滤百叶墙体。图16是多通式分户管箍。图17是多通多舌式空压阀。图18是单层式制冷恒温系统。图19是多功能综合隧洞。
Claims (1)
1.新能源智能保温楼的主要技术特征是:由空气过滤小房1、空气过滤管2、通道3、微隧洞4、空压风机5、管网制冷恒温系统6、多功能综合隧洞7、进气管8、强电9、弱电10、进水管11、进气分户管箍12、排水管13、涡扇风电系统14、综合风洞15、排气风户管箍16、空压阀室内环境控制器17、排气管18、网络传输报警系统19、漏斗20、安全护栏21、内置推拉式增温系统22、折叠式光伏系统23、外置增温系统24、保温玻璃窗25、墙体保温26和楼房主体组成,如图1;生活污水微生物净化系统主要由防渗漏层、保温层、微生物特种种群、污水池、污水进口、排污泵、空压风机、管网、太阳光热增温系统、溢流口、沼气收集利用系统、密封盖等组成;保温玻璃窗是由特制的孔式模具、把融化的金属或非金属经过拉挤成型技术工艺制造成多根肋骨圆弧式T型产品,如图2;多根肋骨圆弧式J型产品,如图3;C型扣槽边缘向外翻折成弧型产品,如图4;∠型扣槽边缘向外翻折成圆弧型产品,如图5;并用连接配件相连接,经过技术工艺加工,制作成多层式保温玻璃窗,玻璃间距主要有相等间距法,如图6;大小间距法如图7;太阳光热玻璃管主要由透光率高的玻璃或钢化玻璃制成圆筒型玻璃管,再把制好的半圆瓦垄式圆筒型太阳光热板插入圆筒型玻璃管内,如图8;是一只直筒型光热玻璃管,或把透光率高的玻璃或钢化玻璃经过吹制或模制工艺技术,首先制造一只圆筒型小直径玻璃直管,直管一端连接带有边缘向外测翻折的环形托盘,托盘上制作有一抽气小孔插入一只透光率高的圆筒型大直径玻璃直管一端连接带有边缘向内侧翻折的环形托盘的直管内,进行熔焊,通过小管把隔层内的空气抽出,再把小管融化,然后再把制好的半圆瓦垄圆筒型光热板插入保温直筒型玻璃管内,如图9;是一只直筒型保温光热玻璃管;通过滚模压制技术工艺系统把金属或非金属板压制成半圆瓦垄型或半气球型板,涂上太阳光热涂料,制成半圆瓦垄型如图10.或半球型如图11是两种太阳能光热板;内置增温系统:主要有推拉折叠式太阳光热板系统如图12或窗帘式两种;外置增温系统主要有多通多孔保温管网式如图13或多通集热箱式如图14或集热墙式三种;空压过滤房是由柱、门、顶和百叶墙体如图15组成;多通式分户管箍是由多通式管箍和舌组成如图16;多通多舌式空压阀主要由多通多舌阀体,舌道,同心轴舌体,转柄,同心轴,封闭盖等组成如图17;管网制冷恒温系统分为单层式和多层式两种,单层式管网制冷恒温系统是把隧洞用管道并联在一起如图18;多功能综合隧洞主要功能是给水系统、排水系统、强电系统、弱电系统、信息监控系统、制冷恒温系统的综合传输如图19。
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Cited By (1)
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CN114636216A (zh) * | 2022-05-17 | 2022-06-17 | 河北化工医药职业技术学院 | 用于独栋别墅的地下室防潮通风系统及方法 |
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CN2806646Y (zh) * | 2005-03-04 | 2006-08-16 | 余太辽 | 太阳能冬暖夏凉楼房 |
CN102011493A (zh) * | 2009-05-05 | 2011-04-13 | 杨正国 | 空压式太阳能保暖房 |
CN102115611B (zh) * | 2010-01-04 | 2013-07-10 | 中国科学院过程工程研究所 | 一种板栗苞汽爆联产色素、栲胶和活性炭的方法 |
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CN2457493Y (zh) * | 2000-07-15 | 2001-10-31 | 刘宏昌 | 冷暖两用地温空调装置 |
CN2806646Y (zh) * | 2005-03-04 | 2006-08-16 | 余太辽 | 太阳能冬暖夏凉楼房 |
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CN114636216B (zh) * | 2022-05-17 | 2022-08-05 | 河北化工医药职业技术学院 | 用于独栋别墅的地下室防潮通风系统及方法 |
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