废旧冰箱拆解聚氨酯泡沫塑料制备PU/PP复合材料

利用废旧冰箱拆解的聚氨酯泡沫塑料(PU)和聚丙烯(PP)、聚丙烯接枝马来酸酐(PP-g-MAH)为原料,采用物理化学回收技术制备PU/PP复合材料。用正交实验法分析PU填充量、PU粒径和PP-g-MAH 3个因素对PU/PP复合材料力学性能影响的显著性。结果表明,PU填充量对PU/PP复合材料拉伸性能有显著影响,对冲击性能和弯曲性能没有显著影响;在本文的实验范围内,PU粒径对PU/PP复合材料的力学性能影响不大;而PP-g-MAH投加量对PU/PP复合材料具有一定的影响。确定的优化工艺配方为:PU 40%;PU粒径选择2.00 mm;PP-g-MAH投加量10%。采用优化工艺制备的PU/PP复合材料的密度为1 042.88 kg/m3;冲击强度为2.9 kJ/m2;拉伸强度为10.30 MPa;拉伸模量为1 100 MPa;弯曲强度为18.5 MPa;弯曲模量为733 MPa。     

三烧溴化锂集中制冷空调系统改建设计

武钢三烧区域改建了二台大连三洋蒸汽型双效溴化锂吸收式制冷机。叙述了该改建项目的主机选型、参数选定、设计特点等。     

报废电冰箱的环保处理技术

介绍一种处理报废电冰箱的技术。首先对报废电冰箱进行分解,包括制冷剂回收、压缩机拆卸、散热系统和蒸发系统拆卸、箱体箱门钢板拆卸、箱体内胆拆卸、门衬拆卸和绝热泡沫剥离等。然后对于拆出的材料作进一步处理,钢板、管材经平整或矫直裁剪之后作为旧板材或旧管材;内胆和门衬破碎后作为注塑材料使用;压缩机组经专业检测、修复再利用或作为冶金炉料使用。聚氨酯泡沫需经分离回收R11处理,处理工艺路线包括泡沫粉碎、发泡剂蒸发、混合气收集、除尘、储气、压缩、冷凝、节流以及发泡剂与空气的分离;工艺参数涉及主要工艺环节的热力学计算,包括破碎后的泡沫中的R11发泡剂的蒸发吸热、混合气压缩功耗、冷凝过程的散热。同时还介绍了应用发泡胶接法的聚氨酯硬泡沫碎屑再成型技术。采用该工艺处理报废电冰箱,具有拆解物利用价值高、处理过程能耗低、便于分拣、设备造价低等优点,适合我国国情。     

我国废旧电冰箱聚氨酯泡沫塑料管理现状及对策研究

随着科技进步和电冰箱产品更新换代速度的加快,报废弃电冰箱数量不断增大.冰箱拆解处理产生的大量聚氨酯泡沫塑料,由于其中含有CFCs类发泡剂且其难以降解等,增加了处理难度,如何对其进行有效处理处置成为国内外广泛关注的焦点.目前我国废弃电冰箱聚氨酯泡沫塑料一般送至生活垃圾处理厂进行焚烧或填埋处置,而未进行资源化利用.在调研电冰箱聚氨酯泡沫塑料国内外现有处理处置技术基础上,比较了热能回收法、物理法、化学法、生物法和热解法等处理技术的优缺点,并对其经济性和实用性进行分析.同时分析了我国废电冰箱聚氨酯泡沫塑料环境管理面临的主要问题,结合国家相关管理政策需求,提出了针对性建议.     

废旧冰箱塑料回收再生利用技术研究

目前我国的废旧冰箱已进入了一个报废高峰期，且大量废旧冰箱塑料的处理问题已成为当今地球环境保护的热点问题，而我国又是一个人均资源占有量很低的国家，因此，对废旧冰箱塑料进行回收与再生利用则具有极其重要的意义。介绍了废旧冰箱塑料的物理再生利用、化学再生利用、生物降解、能源回收利用的技术和方法。     

中国人居空间环境污染状况及防治策略--室内、汽车、冰箱的污染情况及防治方法

随着社会的发展，人们在室内和汽车内的时间占人一生中总的时间的90％还多。而且室内环境的好坏直接影响我们的身体健康。同时冰箱引起的健康问题逐渐被人们所重视。     

Biodegradation of waste refrigerator polyurethane by mealworms

● Waste refrigerator polyurethane (WRPU) was ingested and biodegraded by mealworms. ● The carbon in WRPU-based frass was lower than that in WRPU. ● Urethane groups in WRPU were broken down after ingestion by mealworms. ● Thermal stability of WRPU-based frass were deteriorated compared to that of WRPU. ● Gut microbiomes of mealworms fed using WRPU were distinct from that fed using bran. Refrigerator insulation replacement results in discarding a large amount of waste refrigerator polyurethane (WRPU). Insect larvae like mealworms have been used to biodegrade pristine plastics. However, knowledge about mealworms degrading WRPU is scarce. This study presents an in-depth investigation of the degradation of WRPU by mealworms using the micro-morphology, composition, and functional groups of WRPU and the egested frass characteristics. It was found that the WRPU debris in frass was scoured, implying that WRPU was ingested and degraded by mealworms. The carbon content of WRPU-based frass was lower than that of WRPU, indicating that mealworms utilized WRPU as a carbon source. The urethane groups in WRPU were broken, and benzene rings’ C=C and C–H bonds in the isocyanate disappeared after being ingested by mealworms. Thermal gravimetric-differential thermal gravimetry analysis showed that the weight loss temperature of WRPU-based frass was 300 °C lower than that of WRPU, indicating that the thermal stability of WRPU deteriorated after being ingested. The carbon balance analysis confirmed that carbon in the ingested WRPU released as CO₂ increased from 18.84 % to 29.80 %, suggesting that WRPU was partially mineralized. The carbon in the mealworm biomass ingesting WRPU decreased. The possible reason is that WRPU does not supply sufficient nutrients for mealworm growth, and the impurities and odor present in WRPU affect the appetite of the mealworms. The microbial community analysis indicated that WRPU exerts a considerable effect on the gut microorganism of mealworms. These findings confirm that mealworms degrade WRPU.     

Effect of PCM on temperature fluctuation during the door opening of a household refrigerator

Temperature fluctuation inside the cabinet of a household refrigerator significantly affects the quality of preserved food. Phase change material (PCM) is a latent heat storage system that can store and release the heat energy by changing its phase from liquid to solid and solid to liquid respectively. Therefore, use of PCM inside the refrigerator cabinet has the potential for minimizing the temperature fluctuation during the door opening and the power failure. However, very few studies in the literature were dedicated to investigating the role of PCM to reduce the temperature fluctuation. The aim of this work is to experimentally investigate the effects of PCM on temperature fluctuation inside the cabinet of a household refrigerator during the door opening and power failure. The results found that a significantly lower temperature fluctuation can be obtained using PCM. It was found that during the door opening condition the air temperature in the cabinet rose rapidly. However, when a PCM container was used, temperature variation was reduced to 3–5°C. During the power failure, the system with PCM maintained a lower temperature inside the storage chamber for a long period of time (about 2 hours). Moreover, the test results indicate that PCM maintains more stable temperature in the foodstuffs inside the refrigerator. This reduction of temperature fluctuation ultimately improves the quality of preserved food.     

Environmental friendly automated line for recovering the cabinet of waste refrigerator

A large amount of hazardous trichloromonofluoromethane (CFC-11) is contained in the polyurethane (PUR) foam of refrigerator cabinet. How to recover the cabinet of waste refrigerator with environmental awareness has been the pressing problem in the treatment of waste refrigerator. The published literature of waste refrigerator cabinets recovering mainly focuses on policy making and conceptual design. Little information relates to the production line of waste refrigerator cabinet recovering and its detailed operation, which is the urgent needed literature. In this paper, an environmental friendly production line for recovering the cabinet of waste refrigerators was reported for helping enterprise or government to construct line to recover the obsolete refrigerators. It included closed shearing process, activated carbon fiber absorption (ACFA) process, air current separation, and magnetic/eddy current separation. The optimized operating parameters of every process were obtained from the experiments. Then, experiment of recovering 50 waste refrigerator cabinets by the production line was performed in factory. Mass balances of the recovered materials were carried out. The result shown the recovery rate of waste refrigerator cabinet could reach 97.6%. Finally, comparison between the production line and other recovery technologies was made. The results indicated that the proposed line provided environment-friendly recovery of waste refrigerator cabinets while achieving low cost of production.     

废电冰箱的环保处理及污染防治

通过对废电冰箱隔热泡沫材料的构成、数量、污染物类型及对大气层的污染破坏机理的分析，提出了废电冰箱这种特殊固体废弃物的环保处理技术方法和工艺特点，并介绍了发达国家和地区正在使用的成熟的工艺技术路线及技术指标。