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高职院校“供热通风与空调工程技术专业”实训室的建设摘 要:高职高专院校实训基地是培养职业实践能力的核心条件,而实训室是组织实践教学、强化技能培养、实现人才培养目标的重要基地。建立满足基于“工作过程”项目导向教学的实训室是必要,能保证学生在校期间学习有一个真实的工作环境,为培养学生的技术应用能力提供保证。实训室应具有高新的技术内涵、逼真的实训环境、完备的设备配置、配套的实训教材、科学的组织管理。关键词:高职教育;竞争力;能力;素质由于我国的高等职业教育在起步较晚,其人才培养模式基本上是以学科为核心的普通教育模式,强调培养的学生具有扎实的理论基础、具有一定的研究和设计能力,还没有完全形成培养职业人才的教育体系和教育模式。相应的实验室也满足不了培养职业人才的要求。现有高职院校的实验室基本上是本科和中专学校的原有实验室,而本科院校的实验室是以理论研究和验证为主,中专学校的实验室是以教学演示为主,两者均缺乏培养学生动手操作能力、分析和解决问题能力的功能。如何搞好高等职业院校实验室建设,使其能更好地为教学服务以满足培养高素质职业人才的要求,是迫切需要解决的问题。我院的“供热通风与卫生工程技术”专业为中德联合办学的首批试点专业,省级重点专业。通过与德国专家的全面合作,我们制定了“面向实践的课程”体系和人才培养模式。该课程体系打破了传统的“老三段”式的教学模式,把和专业教学有关的“基础课”、“专业基础课”和“专业课”合并成“职业技术课”,所有“职业技术课”按专业特点进行整合,分别在“供热”、“给排水”和“通风空调”三个实验室内组织教学。因此,这三个实验室的建设对课程体系的改革至关重要。下面就这三个实验室的建设谈谈自己的看法。 1 应以服务课堂教学为建设宗旨原来的课堂教学大多数是在教室内进行,实验室内进行的教学演示实验和验证实验相对很少,即使建设了设备先进的实验室,对课堂教学来讲,利用率也是极低的,造成了资源的大量浪费。由于人才培养模式的不同,工科高等职业院校实验室的建设与同类型的本科院校有很大差异,它不需要过多地进行教学演示实验和验证实验,其重点应放在为课堂教学服务上。通过对高职的人才培养模式的研究和借鉴德国的成功经验,我们制定了一个既能适应“面向实践的课程”体系又能提高实验设备的利用率的教学实验室的建设计划,该计划的最大特点是将课堂教学改在实验室内进行,即把实验室作为课堂教学的主要场所,这就要求实验室除满足实验教学外更主要的应满足课堂教学要求。这样的实验室与传统的实验室有很大的不同,实验室的功能、系统的组成、设备的布置等都有较大变化。“供热通风与卫生工程技术”专业的教学内容,主要是讲授“供热”、“给排水”和“通风空调”系统的组成和分类、热力和水力计算、设备选型计算、安装及运行管理等方面的知识。按三大系统建立三个实验室,分三条教学主线组织教学,所有的专业教学均在三个实验室内进行。三个实验室分别建有各种类型的供热系统、给水排水系统、通风空调系统,教师在实验室内参照各种系统讲授、提出问题并和学生一同解决问题。这样的教学与传统的学科教学相比很多优点。第一,教学直观方便,系统中所有的设备、管路、附件、仪表均为实物就地安装,教师按实物讲解它们的构造、工作原理、安装位置等,既方便又直观。第二,系统的整体感较强,系统中所有的设备、管路、附件、仪表均安装在同一实验室内,使学生一眼就能看出系统的整体结构,不存在传统的学科教学中首尾分离的现象。第三,教学过程中师生可以互动,能充分调动学生学习的积极性。 2 应注重学生动手能力、分析和解决问题能力的培养工科高等职业院校主要培养的是技术应用型人才,学生应具有较强的动手操作能力、分析和解决问题的能力,而这些能力的培养主要是在校内学习期间完成的。培养学生动手能力、分析和解决问题能力可以有很多途径,除了参加社会实践、毕业实习外,在校内建立高标准的实验、实训基地是最为有效的方法。我们的实验室建设从一开始构思就把学生动手能力、分析问题和解决问题能力的培养问题放在了首位。从实验室整体设计到系统某一局部的细化处理处处都考虑上述问题,贯穿始终。如“供热实验室”设计时,我们首先考虑把系统中的供热热源、泵站、热力分配站、热用户用管道连接组合成一个完整的、实际的供热系统,系统中安装有各种管路附件、热工检测和控制仪表、实验用仪表等。锅炉点火、水泵启动这个系统就可以运行。而过去的这些实验室(台)均是独立的,没有形成整体。学生可以通过锅炉点火、水泵启动、锅炉烟气测定、热工和水力参数检测、维护管理等培养其动手操作能力。由于系统是一个实际运行的整体,各设备、附件、仪表相互关联,可以通过系统运行、参数调节及人为故障设定等培养学生分析问题、解决问题的能力。这在过去的课堂上和分散的实验室里是绝对做不到的。 3 应密切结合生产实际我们培养学生的目标是毕业即顶岗、毕业即就业,也就是说学生毕业到工作单位后能够胜任自己的工作。对“供热通风与卫生工程技术”专业来讲,毕业生应能独立完成一般的安装工程施工、施工管理及暖通空调系统运行管理等工作。为了达到这一目标,所建设的实验室要和生产实际紧密结合。我们实验室内安装的系统应为生产实际中常见的系统,所选的设备应为生产实际中常用的设备,并且尽可能采用新工艺、新材料、新设备,也就是说实验室内的系统、设备和材料要比生产实际所采用的要更好更新。这就要求教师除正常教学外,要积极参加本专业的学术活动,及时了解本专业的新技术和新工艺,更好的服务于教学。 4 加强厂校合作,保证设备及时更新实验室建成后,经过一段时间的使用,随着技术的进步,其系统和设备就要落后,如何对落后的技术和设备进行更新,是每一个实验室都要面对的问题。与其他专业不同,暖通工程中使用的设备种类繁多且更新较快。为了使我们的实验室能更好地服务于教学、服务于生产,就要求其系统、设备和材料按工程实际不断地进行更新,对于学校来讲这是一笔不小的费用。我们的做法是,利用我们的技术优势和生产厂家的设备资源,积极开展厂校合作,互惠互利,及时更新实验设备。比如某厂家生产出了新型的设备,可免费安装在我们的实验室内,生产厂家可以以我们的实验室作为基地,进行产品宣传、组织用户参观、对用户进行安装和运行等方面的培训。我们也可以免费为他们进行性能测试、产品鉴定等。通过这种合作方式使我们和生产厂家都受益,真正实现了互惠互利。目前我们已经和多个生产厂家达成了这样的协议。实践教学是达到教学要求、实现培养目标、保证教学质量、提高教学效益的重要环节,必须科学合理建立相应的专业实验实训室及其配套管理机制。建设好高职院校专业实验实训室,提高学生综合技能,提高就业率,是所有高职院校领导和老师的期望,是企业、社会进行市场竞争的需要,需要建设者付出大量辛勤的劳动和汗水。
区域供热,如果你是搞采暖的
可以写作
1、暖通空调:室内或车内负责暖气、通风及空气调节的系统或相关设备。暖通空调系统的设计应用到热力学、流体力学及流体机械,是机械工程领域中的重要分支学科。2、中央空调:采用液体气化制冷的原理为空气调节系统提供所需冷量,用以抵消室内环境的热负荷;制热系统为空气调节系统提供所需热量,用以抵消室内环境冷暖负荷。三、特点不同1、暖通空调:空气进来以后,可以把空气进行冷却处理,然后就进行过滤处理,过滤处理以后,增加电子除尘器可以捕捉非常小的颗粒的灰尘,可以捕捉一个微米的灰尘,而这个灰尘的范围内大部分都是细菌、病毒、烟尘,或者是异味这样就都可以过滤掉。2、中央空调:采用模块化主机,根据设置自动调节制冷量。合理的将白天生活和晚上生活区域分别安装空调,室内及分区控制,各个室内及独立运行,分别调节各个区域内的空气。1、暖通空调:室内或车内负责暖气、通风及空气调节的系统或相关设备。暖通空调系统的设计应用到热力学、流体力学及流体机械,是机械工程领域中的重要分支学科。2、中央空调:采用液体气化制冷的原理为空气调节系统提供所需冷量,用以抵消室内环境的热负荷;制热系统为空气调节系统提供所需热量,用以抵消室内环境冷暖负荷。三、特点不同1、暖通空调:空气进来以后,可以把空气进行冷却处理,然后就进行过滤处理,过滤处理以后,增加电子除尘器可以捕捉非常小的颗粒的灰尘,可以捕捉一个微米的灰尘,而这个灰尘的范围内大部分都是细菌、病毒、烟尘,或者是异味这样就都可以过滤掉。2、中央空调:采用模块化主机,根据设置自动调节制冷量。合理的将白天生活和晚上生活区域分别安装空调,室内及分区控制,各个室内及独立运行,分别调节各个区域内的空气。1、暖通空调:室内或车内负责暖气、通风及空气调节的系统或相关设备。暖通空调系统的设计应用到热力学、流体力学及流体机械,是机械工程领域中的重要分支学科。2、中央空调:采用液体气化制冷的原理为空气调节系统提供所需冷量,用以抵消室内环境的热负荷;制热系统为空气调节系统提供所需热量,用以抵消室内环境冷暖负荷。三、特点不同1、暖通空调:空气进来以后,可以把空气进行冷却处理,然后就进行过滤处理,过滤处理以后,增加电子除尘器可以捕捉非常小的颗粒的灰尘,可以捕捉一个微米的灰尘,而这个灰尘的范围内大部分都是细菌、病毒、烟尘,或者是异味这样就都可以过滤掉。2、中央空调:采用模块化主机,根据设置自动调节制冷量。合理的将白天生活和晚上生活区域分别安装空调,室内及分区控制,各个室内及独立运行,分别调节各个区域内的空气。1、暖通空调:室内或车内负责暖气、通风及空气调节的系统或相关设备。暖通空调系统的设计应用到热力学、流体力学及流体机械,是机械工程领域中的重要分支学科。2、中央空调:采用液体气化制冷的原理为空气调节系统提供所需冷量,用以抵消室内环境的热负荷;制热系统为空气调节系统提供所需热量,用以抵消室内环境冷暖负荷。三、特点不同1、暖通空调:空气进来以后,可以把空气进行冷却处理,然后就进行过滤处理,过滤处理以后,增加电子除尘器可以捕捉非常小的颗粒的灰尘,可以捕捉一个微米的灰尘,而这个灰尘的范围内大部分都是细菌、病毒、烟尘,或者是异味这样就都可以过滤掉。2、中央空调:采用模块化主机,根据设置自动调节制冷量。合理的将白天生活和晚上生活区域分别安装空调,室内及分区控制,各个室内及独立运行,分别调节各个区域内的空气。
高职院校“供热通风与空调工程技术专业”实训室的建设摘 要:高职高专院校实训基地是培养职业实践能力的核心条件,而实训室是组织实践教学、强化技能培养、实现人才培养目标的重要基地。建立满足基于“工作过程”项目导向教学的实训室是必要,能保证学生在校期间学习有一个真实的工作环境,为培养学生的技术应用能力提供保证。实训室应具有高新的技术内涵、逼真的实训环境、完备的设备配置、配套的实训教材、科学的组织管理。关键词:高职教育;竞争力;能力;素质由于我国的高等职业教育在起步较晚,其人才培养模式基本上是以学科为核心的普通教育模式,强调培养的学生具有扎实的理论基础、具有一定的研究和设计能力,还没有完全形成培养职业人才的教育体系和教育模式。相应的实验室也满足不了培养职业人才的要求。现有高职院校的实验室基本上是本科和中专学校的原有实验室,而本科院校的实验室是以理论研究和验证为主,中专学校的实验室是以教学演示为主,两者均缺乏培养学生动手操作能力、分析和解决问题能力的功能。如何搞好高等职业院校实验室建设,使其能更好地为教学服务以满足培养高素质职业人才的要求,是迫切需要解决的问题。我院的“供热通风与卫生工程技术”专业为中德联合办学的首批试点专业,省级重点专业。通过与德国专家的全面合作,我们制定了“面向实践的课程”体系和人才培养模式。该课程体系打破了传统的“老三段”式的教学模式,把和专业教学有关的“基础课”、“专业基础课”和“专业课”合并成“职业技术课”,所有“职业技术课”按专业特点进行整合,分别在“供热”、“给排水”和“通风空调”三个实验室内组织教学。因此,这三个实验室的建设对课程体系的改革至关重要。下面就这三个实验室的建设谈谈自己的看法。 1 应以服务课堂教学为建设宗旨原来的课堂教学大多数是在教室内进行,实验室内进行的教学演示实验和验证实验相对很少,即使建设了设备先进的实验室,对课堂教学来讲,利用率也是极低的,造成了资源的大量浪费。由于人才培养模式的不同,工科高等职业院校实验室的建设与同类型的本科院校有很大差异,它不需要过多地进行教学演示实验和验证实验,其重点应放在为课堂教学服务上。通过对高职的人才培养模式的研究和借鉴德国的成功经验,我们制定了一个既能适应“面向实践的课程”体系又能提高实验设备的利用率的教学实验室的建设计划,该计划的最大特点是将课堂教学改在实验室内进行,即把实验室作为课堂教学的主要场所,这就要求实验室除满足实验教学外更主要的应满足课堂教学要求。这样的实验室与传统的实验室有很大的不同,实验室的功能、系统的组成、设备的布置等都有较大变化。“供热通风与卫生工程技术”专业的教学内容,主要是讲授“供热”、“给排水”和“通风空调”系统的组成和分类、热力和水力计算、设备选型计算、安装及运行管理等方面的知识。按三大系统建立三个实验室,分三条教学主线组织教学,所有的专业教学均在三个实验室内进行。三个实验室分别建有各种类型的供热系统、给水排水系统、通风空调系统,教师在实验室内参照各种系统讲授、提出问题并和学生一同解决问题。这样的教学与传统的学科教学相比很多优点。第一,教学直观方便,系统中所有的设备、管路、附件、仪表均为实物就地安装,教师按实物讲解它们的构造、工作原理、安装位置等,既方便又直观。第二,系统的整体感较强,系统中所有的设备、管路、附件、仪表均安装在同一实验室内,使学生一眼就能看出系统的整体结构,不存在传统的学科教学中首尾分离的现象。第三,教学过程中师生可以互动,能充分调动学生学习的积极性。 2 应注重学生动手能力、分析和解决问题能力的培养工科高等职业院校主要培养的是技术应用型人才,学生应具有较强的动手操作能力、分析和解决问题的能力,而这些能力的培养主要是在校内学习期间完成的。培养学生动手能力、分析和解决问题能力可以有很多途径,除了参加社会实践、毕业实习外,在校内建立高标准的实验、实训基地是最为有效的方法。我们的实验室建设从一开始构思就把学生动手能力、分析问题和解决问题能力的培养问题放在了首位。从实验室整体设计到系统某一局部的细化处理处处都考虑上述问题,贯穿始终。如“供热实验室”设计时,我们首先考虑把系统中的供热热源、泵站、热力分配站、热用户用管道连接组合成一个完整的、实际的供热系统,系统中安装有各种管路附件、热工检测和控制仪表、实验用仪表等。锅炉点火、水泵启动这个系统就可以运行。而过去的这些实验室(台)均是独立的,没有形成整体。学生可以通过锅炉点火、水泵启动、锅炉烟气测定、热工和水力参数检测、维护管理等培养其动手操作能力。由于系统是一个实际运行的整体,各设备、附件、仪表相互关联,可以通过系统运行、参数调节及人为故障设定等培养学生分析问题、解决问题的能力。这在过去的课堂上和分散的实验室里是绝对做不到的。 3 应密切结合生产实际我们培养学生的目标是毕业即顶岗、毕业即就业,也就是说学生毕业到工作单位后能够胜任自己的工作。对“供热通风与卫生工程技术”专业来讲,毕业生应能独立完成一般的安装工程施工、施工管理及暖通空调系统运行管理等工作。为了达到这一目标,所建设的实验室要和生产实际紧密结合。我们实验室内安装的系统应为生产实际中常见的系统,所选的设备应为生产实际中常用的设备,并且尽可能采用新工艺、新材料、新设备,也就是说实验室内的系统、设备和材料要比生产实际所采用的要更好更新。这就要求教师除正常教学外,要积极参加本专业的学术活动,及时了解本专业的新技术和新工艺,更好的服务于教学。 4 加强厂校合作,保证设备及时更新实验室建成后,经过一段时间的使用,随着技术的进步,其系统和设备就要落后,如何对落后的技术和设备进行更新,是每一个实验室都要面对的问题。与其他专业不同,暖通工程中使用的设备种类繁多且更新较快。为了使我们的实验室能更好地服务于教学、服务于生产,就要求其系统、设备和材料按工程实际不断地进行更新,对于学校来讲这是一笔不小的费用。我们的做法是,利用我们的技术优势和生产厂家的设备资源,积极开展厂校合作,互惠互利,及时更新实验设备。比如某厂家生产出了新型的设备,可免费安装在我们的实验室内,生产厂家可以以我们的实验室作为基地,进行产品宣传、组织用户参观、对用户进行安装和运行等方面的培训。我们也可以免费为他们进行性能测试、产品鉴定等。通过这种合作方式使我们和生产厂家都受益,真正实现了互惠互利。目前我们已经和多个生产厂家达成了这样的协议。实践教学是达到教学要求、实现培养目标、保证教学质量、提高教学效益的重要环节,必须科学合理建立相应的专业实验实训室及其配套管理机制。建设好高职院校专业实验实训室,提高学生综合技能,提高就业率,是所有高职院校领导和老师的期望,是企业、社会进行市场竞争的需要,需要建设者付出大量辛勤的劳动和汗水。
建筑热能通风空调、制冷与空调、城市建筑等等均可
暖通方面的论文在品学论文网很多的哦,你可以参考下,如果还有不清楚的地方,可以咨询下他们的在线辅导老师,我之前也是求助他们帮忙的,很快就给我了,当时还是品学论文的王老师帮忙的,态度不错,呵呵,相对于一些小机构和个人要靠谱的多
办公场所中央空调的安装维护中应注意的问题【摘要】本文结合笔者多年的工作经验,介绍了办公场所中央空调安装维护中存在的几个问题,并提出了的具体解决对策。希望对实际工作有所帮助。【关键词】中央空调安装维护;办公场所;存在问题1。空调末端设备嘈声超标与处理空调末端设备运转嘈声超标,是实践过程中最经常碰到的设备嗜声问题。风机盘管由于技术等各方面比较成熟,国内的许多厂家的产品都能达标。而大风机组的情况却不尽如人意,往往嘈声实测值比厂家提供的产品样本参数高出不少。笔者就接触过二例末端设备运转嘈声超标的工程:—个是吊式柜机的进出口都设有消声器,但设备本身的哈声超标太多而从回风口传出来;另—例是吊式柜机的进出口都没设消声器,结果试运转时室内的嘈声实测值远超有关的室内嗜声的标准。这二个工程最后都采用变频器降低风机转速来减少哈声,但空调的制冷效果也受到很大影响。因此,设计中要标出设备的嘈声参数要求,同时对大风量机组设计时应考虑消声隔声措施。在设备进场及时进行设备开箱检查,大风量机组未安装前最好进行通电试运行,发现心声超标问题可以及时进行更换、退货或修改完善消声措施等处理方法,避免安装后进人工程调试阶段才发现机组有嗜声问题而造成大整改情况。2.空调水系统的循环问题与解决水系统在中央空调工程中是最主要也是最关键的环书,出现问题就会直接影响系统的正常工作。中央空调冷冻水系统缓常见的问题冷冻水系统管道循环不良。造成管路循环不良的原因一是管道因各专业管线文叉,施工中没有协调处理好,造成管网出现许多气囊现象,影响管网循环。二是空调水系统管道清洗工作不到位,直接造成空调水系统循环堵塞。根据多年的实践,笔者认为针对第一个问题,处理方法就是加强施工前管理,合理安排管线标高,尽量避免出现气囊现象,同时在不可避免气囊部位要设置排气阀,且将排气阀的排气管接至安全处,以利系统排气。对第二个问题,应该从施工过程就耍做好几方面预防工作:首先是焊接钢管安装前必须用机械或人工清除污垢和锈斑,当管内外壁清理干净后,将管口封闭待装。管道施工过程中未封闭的管口要做临时封堵,以免污物进入,管道连接时要及时清理焊渣和麻丝等杂物。第二,管网项部设自动或手动排气阀,管网的最低处安装—个比较大的排污阀。如排污阀阀门太小,排污效果差,清洗次数要多,如不在最低处,则排污不彻底。最后,管网安装中应适当增设临时过滤器和旁通冲洗阀门,在连接设备之前,结合通水试压进行分段清洗以免污物堵塞设备。清洗工作完成以后,还要进行水系统循环试运行,其目的是将管网中的污物冲洗集中到过滤器,然后再拆洗过滤器清除污物。3.安装不当产生的滴水结礴问题与处理造成空调系统在调试和运行中滴水结睡问题原因很多,归纳起来主要有管道安装和保温二大方面的原因。管道与管件、管道与设备之间连接不严密,造成漏水主要原因有:管道安装没有严格遵守操作规程施工。管材管件材料质量低劣,材料进场时没有进行认真检查。系统没有严格按规范进行水压试验。因冷凝水管安装不当出现常见问题有:(1)冷凝水管路太长,安装时与吊顶打架或坡度难保证甚至是冷凝水管倒坡,造成滴水现象:空调机组的冷凝水管因没有设水封而出现机组的冷凝水无法排除。(2)以上冷凝水管施工中安装向题处理的办法就是冷凝水尽可能就近排放,以避免冷凝水管倒坡积水或与吊顶打架现象;柜机的冷凝水管应按机内的负压大小设水封,以使冷凝水排放畅通。保温引起的主要原因有:保温材料的容重不足或保温材料的厚度不均,结果是运行时保温材料的外表面温度达到露点温度而产生结露。保温材料与管道的外壁结合不紧密。空调水管道的末端未做封闭处理,造成潮气俊人保温层导致结露滴水。穿墙处冷冻管滴水,主要原因是保温不严密或保温材料的防潮层破损。风栅盘管滴水盘排水口被保温材料等杂物堵住,且安装完后没有及时清理和做冷凝水管的灌、排水试验。吊式柜机、风机盘管滴水盘的保温材料受破坏造成滴水盘结露。针对这些问题,主要的解决办法:一是加强保温材料进场的检查。要加强施工前的技术交底和施工中检查,严禁用大保温套管套小管道,加强对弯头、阀门、法兰及设备接口处等细部的保温质量控制力度,确保保温层与管道的外壁结合紧密。三是穿墙部位冷冻管加设保温保护套管,加强检查,确保穿墙部位保温层的连续性和严密性。四是加强对吊顶封板前的对风机盘管滴水盘杂物清理检查。五是加强对设备滴水盘的保护力度,特别是吊顶封板前的检查。4.防火、排烟风阀的选型问题与处理办公场所一旦发生火灾,往往会造成严重的伤亡事故和经济损失。为了将火灾引起的损失减少到最小程度,就必须采取有效的防火、防排烟措施,以控制火势蔓延。而防火、排烟风阀在通风、空调及防排烟系统中的合理设里,则起到了重要的作用。防火阀是指安装在通风、空调系统的送、回风管路上,平时呈开启状态,火灾时当管道内气体温度达到70~C时自动关闭,在一定时间内能满足耐火稳定性和耐火完整性要求,起隔烟阻火作用的阀门;排烟阀是指安装在排烟系统管道上,平时呈关闭状态,火灾时自动打开,当管道内气体温度达到280qC时自动关闭,在一定时间内能满足耐火稳定性和耐火完整性要求,起隔烟阻火作用的阀门。防火、排烟风阀众多的型号主要是由以上二大类演化而来。在空调工程实施的管理工作中,常常会有一些问题.,有些问题还很棘手。这要要我们细致地做好质量控制工作,空调工程施工前要了解设计意图,善于抓住工程的控制要点,做好控制要点的事前、事中、事后管理,施工时有目的、针对性地进行,点控制,这样有利于我们工程质管理工作做得更好。.【参考文献】[1]梁轮文.如何做好中央空调施工管理及安装工作Ⅱ】.四川建材,2006,(o6).[2]黄建强.浅谈空调冷冻系统安装的施工技术Ⅱ】.建材与装饰(下旬刊),2007,(1 1).
楼主算是找对人了。。。正好我有时间。。。商用中央空调的维护和保养 目前,随着商业企业竞争的加剧,购物环境与企业效益有着密切关系。大、中型商场纷纷设计安装中央空调系统。中央空调系统投资费用约占整个投资的10%左右,而平时的运转费用占总能源费用的40%~60%。如南京某商场,夏季空调费用(仅计算电费)就花去了整个夏季总利润的80%左右。对中央空调系统不加维护保养,结果空调制冷效果越来越差,一年不如一年,耗电越来越多,成本越来越高,设备损坏很严重,有些用户的空调系统使用一年多就基本瘫痪。如管理操作人员认真研究制订针对本单位的中央空调系统的特点的维修保养计划,使中央空调始终处于高效、节能工况下运行。 商场中央空调用来调节商场一年四季的温、湿度和补充新鲜空气,提高购物环境的舒适性其特点如下:1、商场内人员密度高(一般每天客流量峰值经常出现在上午10~11时,下午13~16时,顾客也较集中),尤其在节假日,新风处理量大,因而商场空调夏季制冷负荷大,冬季供暖负荷较小。2、商场内客流量的不稳定性和随机性使得商场空调负荷不稳定,要求空调系统变工况性能好,调节灵敏。3、商场每天营业,四季气候变化大,要求商场空调运转工况与之相适应,既要满足个别恶劣天气的高峰负荷,又要在大部分时间低负荷工况下有良好的经济性能。维护与保养 1冷冻机 商场中央空调系统选用冷源设备会根据电力供应、投资、建筑规模等因素加以考虑,商场中央空调所用机组类型概况,根据调研用户若从这几方面加以重点维护保养的话,则会延长空调设备使用寿命,减缓制冷效率下降的速度。 2水系统 1冷却水系统 由冷凝器、冷却塔、水泵、管道、阀门、过滤器等组成冷却水系统,它的作用是将制冷系统中的热量排放到大气中。中央空调系统中的冷凝器在水侧会逐渐形成一层水垢。冷凝器使用时间越长,水质越硬,其水垢厚度就越厚。因水垢导热系数小,影响冷凝器传热效果,导致冷冻机制冷效果差。因此,必须采取相应的措施去除冷凝器水侧的水垢技术难题。去除冷凝器水侧的水垢传统方法有人工洗刷,机械的和化学清洗。近几年有些商场中央空调冷却水系统安装电子水处理仪后因该仪器本身的工作原理决定无法去除水中杂质只有通过排污达到防垢除垢的目的,而空调操作人员往往忽略这一点。安装了电子水处理仪则无需排污这是错误的理解。其每一种方法都有不足之处。这就会出现只有当冷凝器水侧的水垢影响到整个制冷系统正常工作之后才会清洗冷凝器的水垢。新一代水处理仪具有测量水温和水中总固体溶解度,然后自动调整仪器的运行参数。但排污工作仍不可忽视。 军团病感染及其对策:1976年在美国费城发现军团病。1981年在南京发现首例军团病例。军团病菌的生存条件是:当水温在25℃——42℃(其中水温37℃繁殖最快),水体滞流,水中含有大量的水垢、沉淀物、微生物膜及变形虫等会迅速繁殖并可能达到威胁人体健康。 中央空调设备中的冷却水系统给军团病菌的生存和繁殖提供了有利条件:其一,冷却水温在31℃——35℃;其二,大量的空气经冷却水的洗涤,灰尘、有机物和微生物及其残骸在冷却水系统中堆积,这些物质为军团病菌的繁殖提供营养来源。这样对冷却塔及管道的清洁工作可减少军团病菌生长所需养料。 预防军团病有效措施:A定期在冷却塔循环水中投放消毒杀菌剂和灭藻剂,针对军团菌台湾某公司生产的ARKO—400杀菌灭藻剂对军团菌抑制与杀灭均有极佳效果,解决冷却水塔因日照,长满青苔而造成污塞之困扰。每周添加一次。B定期清洗冷却水盘和蓄水池,清除水中微生物藉以作为营养源的腐败杂物从而减少微生物的繁殖,建议一年清洗1—2次可用广东某厂生产高级空调水垢清除剂进行清洗,快速方便。C定期检查水质,根据水质情况决定换水的时间。D保证一定量的补充水,以降低冷却水蒸发浓缩的程度。 2冷媒水系统 冷媒水系统的用水一般都采用自来水,水在系统中不与空气接触,不受阳光照射,水质不易变坏。水质变坏时,其主要原因也不是结垢,而是腐蚀。这些腐蚀是由于补充水带入的氧气,各种不同金属材料引起的电偶腐蚀以及厌氧微生物的生长所引起。腐蚀所形成的污泥,也会造成水质变坏、管路堵塞,尤其是风机盘管水过滤器容易堵塞,影响制冷效果,时间一长还会产生泄漏。台湾某公司产的密闭系统腐蚀抑制剂ARKO—501加入冷媒水系统后可以有效地对管路系统中所有金属有防蚀效果均极佳,并具有防止沉淀物形成,用户只需每周添加一次。 3末端设备维护保养与室内空气品质 1风机盘管、新风机组、表冷器及组合式空调箱维护与保养 中央空调系统末端设备对空气进行热、湿处理后达到设定值之后被送往空调房间,这些设备在使用后会出现一些常见故障并提出了解决这些问题的对策。2室内空气品质与空气净化设备 商场里空气质量低劣的原因是:a、商场里通风不良,空调系统的空气过滤不佳,在人、商场、空调机三者之间形成一个封闭的循环系统,在这个系统中,人体无法得到充足的新鲜空气,因此导致一些体弱顾客或营业员在商场里昏厥。据了解人体所需的充足氧气浓度标准应为21%。医学监测数据表明,生活空间如果几小时不通风氧气浓度将下降到17~19%,从而影响到人体对氧气的正常需求,以致头晕目眩浑身乏力。b、商场内建筑装璜材料、各种家具不断散发出甲醛、氯化物、苯等有毒有害物质,浓度甚高。c、顾客、营业员在商场内活动,通过呼吸道、汗腺排出大量污染物。d、商场一般都设置在交通便捷地段,车辆众多,汽车排出的尾气不可避免地窜入到商场里来。为了营造良好的购物环境对室内空气进行技术处理是必要的。表3给出了紫外线杀菌技术、安装位置、效果、作用及应用场合。定期或不定期清洗过滤器,选用合格的过滤器,可以避免风口处沾满黑渍,影响顾客在商场的购物欲望。结论与建议 对制冷机及系统,按操作维修规程每年检修一次;重视水质处理;定期清洗末端设备过滤器;对维修管理运行部门的负责人和工作人员,要进行针对性的培训,以便使他们全面了解和熟悉采暖通风和空调系统的管理控制和维修技术;研究顾客在商场购物时对环境的要求,向运行管理技术人员提供每月的能量损耗和费用,以便管理人员重视能耗情况,制定下一个月的节能运行指标,将每年同一个月的室外气温及当月耗能制成表格,可供运行管理技术人员参考。
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制冷RefrigerationRefrigeration is the process of removing heat from an enclosed space, or from a substance, and rejecting it elsewhere for the primary purpose of lowering the temperature of the enclosed space or substance and then maintaining that lower The term cooling refers generally to any natural or artificial process by which heat is The process of artificially producing extreme cold temperatures is referred to as Cold is the absence of heat, hence in order to decrease a temperature, one "removes heat", rather than "adding " In order to satisfy the Second Law of Thermodynamics, some form of work must be performed to accomplish This work is traditionally done by mechanical work but can also be done by magnetism, laser or other However, all refrigeration uses the three basic methods of heat transfer: convection, conduction, or Historical applicationsIce harvestingThe use of ice to refrigerate and thus preserve food goes back to prehistoric Through the ages, the seasonal harvesting of snow and ice was a regular practice of most of the ancient cultures: Chinese, Hebrews, Greeks, Romans, P Ice and snow were stored in caves or dugouts lined with straw or other insulating The Persians stored ice in pits called Rationing of the ice allowed the preservation of foods over the cold This practice worked well down through the centuries, with icehouses remaining in use into the twentieth In the 16th century, the discovery of chemical refrigeration was one of the first steps toward artificial means of Sodium nitrate or potassium nitrate, when added to water, lowered the water temperature and created a sort of refrigeration bath for cooling In Italy, such a solution was used to chill During the first half of the 19th century, ice harvesting became big business in A New Englander Frederic Tudor, who became known as the "Ice King", worked on developing better insulation products for the long distance shipment of ice, especially to the First refrigeration systemsThe first known method of artificial refrigeration was demonstrated by William Cullen at the University of Glasgow in Scotland in Cullen used a pump to create a partial vacuum over a container of diethyl ether, which then boiled , absorbing heat from the surrounding The experiment even created a small amount of ice, but had no practical application at that In 1805, American inventor Oliver Evans designed but never built a refrigeration system based on the vapor-compression refrigeration cycle rather than chemical solutions or volatile liquids such as ethyl In 1820, the British scientist Michael Faraday liquefied ammonia and other gases by using high pressures and low An American living in Great Britain, Jacob Perkins, obtained the first patent for a vapor-compression refrigeration system in Perkins built a prototype system and it actually worked, although it did not succeed In 1842, an American physician, John Gorrie, designed the first system for refrigerating water to produce He also conceived the idea of using his refrigeration system to cool the air for comfort in homes and hospitals (, air-conditioning) His system compressed air, then partially cooled the hot compressed air with water before allowing it to expand while doing part of the work required to drive the air That isentropic expansion cooled the air to a temperature low enough to freeze water and produce ice, or to flow "through a pipe for effecting refrigeration otherwise" as stated in his patent granted by the US Patent Office in Gorrie built a working prototype, but his system was a commercial Alexander Twining began experimenting with vapor-compression refrigeration in 1848 and obtained patents in 1850 and He is credited with having initiated commercial refrigeration in the United States by Meanwhile, James Harrison who was born in Scotland and subsequently emigrated to Australia, begun operation of a mechanical ice-making machine in 1851 on the banks of the Barwon River at Rocky Point in G His first commercial ice-making machine followed in 1854 and his patent for an ether liquid-vapour compression refrigeration system was granted in Harrison introduced commercial vapor-compression refrigeration to breweries and meat packing houses and by 1861, a dozen of his systems were in Australian, Argentinean and American concerns experimented with refrigerated shipping in the mid 1870s, the first commercial success coming when William Soltau Davidson fitted a compression refrigeration unit to the New Zealand vessel Dunedin in 1882, leading to a meat and dairy boom in Australasia and South AThe first gas absorption refrigeration system using gaseous ammonia dissolved in water (referred to as "aqua ammonia") was developed by Ferdinand Carré of France in 1859 and patented in Due to the toxicity of ammonia, such systems were not developed for use in homes, but were used to manufacture ice for In the United States, the consumer public at that time still used the ice box with ice brought in from commercial suppliers, many of whom were still harvesting ice and storing it in an Thaddeus Lowe, an American balloonist from the Civil War, had experimented over the years with the properties of One of his mainstay enterprises was the high-volume production of hydrogen He also held several patents on ice making His "Compression Ice Machine" would revolutionize the cold storage In 1869 he and other investors purchased an old steamship onto which they loaded one of Lowe’s refrigeration units and began shipping fresh fruit from New York to the Gulf Coast area, and fresh meat from Galveston, Texas back to New Y Because of Lowe’s lack of knowledge about shipping, the business was a costly failure, and it was difficult for the public to get used to the idea of being able to consume meat that had been so long out of the packing Domestic mechanical refrigerators became available in the United States around Widespread commercial useBy the 1870s breweries had become the largest users of commercial refrigeration units, though some still relied on harvested Though the ice-harvesting industry had grown immensely by the turn of the 20th century, pollution and sewage had begun to creep into natural ice making it a problem in the metropolitan Eventually breweries began to complain of tainted This raised demand for more modern and consumer-ready refrigeration and ice-making In 1895 German engineer Carl von Linde set up a large-scale process for the production of liquid air and eventually liquid oxygen for use in safe household Refrigerated railroad cars were introduced in the US in the 1840s for the short-run transportation of dairy In 1867 JB Sutherland of Detroit, Michigan patented the refrigerator car designed with ice tanks at either end of the car and ventilator flaps near the floor which would create a gravity draft of cold air through the By 1900 the meat packing houses of Chicago had adopted ammonia-cycle commercial By 1914 almost every location used artificial The big meat packers, Armour, Swift, and Wilson, had purchased the most expensive units which they installed on train cars and in branch houses and storage facilities in the more remote distribution It was not until the middle of the 20th century that refrigeration units were designed for installation on tractor-trailer rigs (trucks or lorries) Refrigerated vehicles are used to transport perishable goods, such as frozen foods, fruit and vegetables, and temperature-sensitive Most modern refrigerators keep the temperature between -40 and +20 °C and have a maximum payload of around 24 000 gross weight (in Europe)Home and consumer useWith the invention of synthetic refrigerations based mostly on a chlorofluorocarbon (CFC) chemical, safer refrigerators were possible for home and consumer Freon is a trademark of the Dupont Corporation and refers to these CFC, and later hydrochlorofluorocarbon (HCFC) and hydrofluorocarbon (HFC), Developed in the late 1920's, these refrigerants were considered at the time to be less harmful than the commonly used refrigerants of the time, including methyl formate, ammonia, methyl chloride, and sulfur The intent was to provide refrigeration equipment for home use without endangering the lives of the These CFC refrigerants answered that The Montreal ProtocolAs of 1989, CFC-based refrigerant was banned via the Montreal Protocol due to the negative effects it has on the ozone The Montreal Protocol was ratified by most CFC producing and consuming nations in Montreal, Quebec, Canada in September Greenpeace objected to the ratification because the Montreal Protocol instead ratified the use of HFC refrigeration, which are not ozone depleting but are still powerful global warming Searching for an alternative for home use refrigeration, dkk Scharfenstein (Germany) developed a propane-based CFC as well as an HFC-free refrigerator in 1992 with assistance from G[citation needed]The tenets of the Montreal Protocol were put into effect in the United States via the Clean Air Act legislation in August The Clean Air Act was further amended in This was a direct result of a scientific report released in June 1974 by Rowland-Molina, detailing how chlorine in CFC and HCFC refrigerants adversely affected the ozone This report prompted the FDA and EPA to ban CFCs as a propellant in 1978 (50% of CFC use at that time was for aerosol can propellant)In January 1992, the EPA required that refrigerant be recovered from all automotive air conditioning systems during system In July 1992, the EPA made illegal the venting of CFC and HCFC In June 1993, the EPA required that major leaks in refrigeration systems be fixed within 30 A major leak was defined as a leak rate that would equal 35% of the total refrigerant charge of the system (for industrial and commercial refrigerant systems), or 15% of the total refrigerant charge of the system (for all other large refrigerant systems), if that leak were to proceed for an entire In July 1993, the EPA instituted the Safe Disposal Requirements, requiring that all refrigerant systems be evacuated prior to retirement or disposal (no matter the size of the system), and putting the onus on the last person in the disposal chain to ensure that the refrigerant was properly In August 1993, the EPA implemented reclamation requirements for If a refrigerant is to change ownership, it must be processed and tested to comply with the American Refrigeration Institute (ARI) standard 700-1993 (now ARI standard 700-1995) requirements for refrigerant In November 1993, the EPA required that all refrigerant recovery equipment meet the standards of ARI 740- In November 1995, the EPA also restricted the venting of HFC These contain no chlorine that can damage the ozone layer (and thus have an ODP (Ozone Depletion Potential) of zero), but still have a high global warming In December 1995, CFC refrigerant importation and production in the US was It is currently planned to ban all HCFC refrigerant importation and production in the year 2030, although that will likely be Current applications of refrigerationProbably the most widely-used current applications of refrigeration are for the air-conditioning of private homes and public buildings, and the refrigeration of foodstuffs in homes, restaurants and large storage The use of refrigerators in our kitchens for the storage of fruits and vegetables has allowed us to add fresh salads to our diets year round, and to store fish and meats safely for long In commerce and manufacturing, there are many uses for Refrigeration is used to liquify gases like oxygen, nitrogen, propane and methane for In compressed air purification, it is used to condense water vapor from compressed air to reduce its moisture In oil refineries, chemical plants, and petrochemical plants, refrigeration is used to maintain certain processes at their required low temperatures (for example, in the alkylation of butenes and butane to produce a high octane gasoline component) Metal workers use refrigeration to temper steel and In transporting temperature-sensitive foodstuffs and other materials by trucks, trains, airplanes and sea-going vessels, refrigeration is a Dairy products are constantly in need of refrigeration, and it was only discovered in the past few decades that eggs needed to be refrigerated during shipment rather than waiting to be refrigerated after arrival at the grocery Meats, poultry and fish all must be kept in climate-controlled environments before being Refrigeration also helps keep fruits and vegetables edible One of the most influential uses of refrigeration was in the development of the sushi/sashimi industry in J Prior to the discovery of refrigeration, many sushi connoisseurs suffered great morbidity and mortality from diseases such as hepatitis A[citation needed], and Diphyllobothriosis, from a common oceanic tapeworm - Diphyllobothrium latum Oiler99 (talk) 19:09, 26 May 2008 (UTC) However the dangers of unrefrigerated sashimi was not brought to light for decades due to the lack of research and healthcare distribution across rural J Around mid-century, the Zojirushi corporation based in Kyoto made breakthroughs in refrigerator designs making refrigerators cheaper and more accessible for restaurant proprietors and the general Methods of refrigerationMethods of refrigeration can be classified as non-cyclic, cyclic and Non-cyclic refrigerationIn these methods, refrigeration can be accomplished by melting ice or by subliming dry These methods are used for small-scale refrigeration such as in laboratories and workshops, or in portable Ice owes its effectiveness as a cooling agent to its constant melting point of 0 °C (32 °F) In order to melt, ice must absorb 55 kJ/kg ( 144 Btu/lb) of Foodstuffs maintained at this temperature or slightly above have an increased storage Solid carbon dioxide, known as dry ice, is used also as a Having no liquid phase at normal atmospheric pressure, it sublimes directly from the solid to vapor phase at a temperature of -5 °C (-3 °F) Dry ice is effective for maintaining products at low temperatures during the period of Cyclic refrigerationMain article: Heat pump and refrigeration cycleThis consists of a refrigeration cycle, where heat is removed from a low-temperature space or source and rejected to a high-temperature sink with the help of external work, and its inverse, the thermodynamic power In the power cycle, heat is supplied from a high-temperature source to the engine, part of the heat being used to produce work and the rest being rejected to a low-temperature This satisfies the second law of A refrigeration cycle describes the changes that take place in the refrigerant as it alternately absorbs and rejects heat as it circulates through a It is also applied to HVACR work, when describing the "process" of refrigerant flow through an HVACR unit, whether it is a packaged or split Heat naturally flows from hot to Work is applied to cool a living space or storage volume by pumping heat from a lower temperature heat source into a higher temperature heat Insulation is used to reduce the work and energy required to achieve and maintain a lower temperature in the cooled The operating principle of the refrigeration cycle was described mathematically by Sadi Carnot in 1824 as a heat The most common types of refrigeration systems use the reverse-Rankine vapor-compression refrigeration cycle although absorption heat pumps are used in a minority of Cyclic refrigeration can be classified as:Vapor cycle, and Gas cycle Vapor cycle refrigeration can further be classified as:Vapor compression refrigeration Vapor absorption refrigeration
If the entering air condition ischanged to Point D at the same wet-bulb temperature but at a higherdry-bulb temperature, the total heat transfer (Vector DB) remainsthe same, but the sensible and latent components change dramati- DE represents sensible cooling of air, while EB representslatent heating as water gives up heat and mass to the Thus, forthe same water-cooling load, the ratio of latent to sensible heattransfer can vary The ratio of latent to sensible heat is important in analyzing waterusage of a cooling Mass transfer (evaporation) occurs only inthe latent portion of heat transfer and is proportional to the changein specific Because the entering air dry-bulb temperatureor relative humidity affects the latent to sensible heat transfer ratio,it also affects the rate of In Figure 2, the rate of evapo-ration in Case AB (WB − WA) is less than in Case DB (WB − WD)because the latent heat transfer (mass transfer) represents a smallerportion of the The evaporation rate at typical design conditions is approximately1% of the water flow rate for each 7 K of water temperature range;however, the average evaporation rate over the operating season isless than the design rate because the sensible component of total heattransfer increases as entering air temperature In addition to water loss from evaporation, losses also occurbecause of liquid carryover into the discharge airstream and blow-down to maintain acceptable water 如果是进入空调改为D点在同一湿球温度,但在较高干球温度,总传热(矢量数据库)仍然相同,但明智的和潜在的组成部分的剧作家,卡利。明智署署长代表空气冷却,而电子束代表潜热,水热,放弃了对空气质量。因此,同样的水冷却负荷,潜显热比转移有很大的差别。对潜在的比例显热分析是很重要的水使用的冷却塔。传质(蒸发)只发生在潜在的传热部分,是成比例的改变在具体的湿度。由于进入空气干球温度或相对湿度影响潜到显热传递率,它也影响到蒸发率。在图2中,土壤水分蒸发的速度,在个案公司(世行 - WA)的比例是比案例数据库(世行 - 西数较少)因为潜热转移(质)代表一个较小的部分总额。在典型的设计条件下蒸发率约为1%的水每7 K表温度范围内水流量;但是,在工作赛季平均蒸发量低于设计速度,因为总热量合理成分作为进入空气温度降低转移增加。除了水的蒸发损失,损失也可能发生由于结转到液体排放气流吹到保持可接受的水质。