为南非开发具有高热能收集能力的大面积低成本太阳能热水系统

IF 0.6 4区工程技术 Q4 ENERGY & FUELS

Journal of Energy in Southern Africa Pub Date : 2019-03-22 DOI:10.17159/2413-3051/2019/V30I1A5226

Monga F. Twite, L. Snyman, J. De Koker, A. Yusuff

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引用次数: 4

摘要

南非为家庭应用开发了一种可用于高压/低压隔离太阳能热水系统的低成本热交换器系统。铜线圈和电加热器的组合可以隔离系统的高压和低压部分，并且可以利用大型低成本太阳能吸热平台，在低压下运行，结垢和泄漏的风险很低。该设计包括安装在传统间歇泉内的铜圈热交换器，以取代传统商用家用间歇泉中的正常加热元件和恒温系统。电热元件仍然补充系统在低太阳能条件下。系统中的循环是由一个小的独立光伏板和一个循环泵创造的。一个集成开关允许系统根据当时的天气条件在传统电加热和太阳能热水之间交替。目前的测试表明，该系统的面积为15平方米，安装成本约为10,000 - 12,000兰特。该系统可以以每千瓦时约12美分的价格提供热水，每天的总储热容量高达10千瓦时。这意味着客户每月最多可节省600兰特。在该产品的十年寿命中，累计为一个家庭节省的费用估计为20万南非兰特。目前在当地市场上，一个2平方米的集热器的热能存储容量约为每天1千瓦时。因此，实现了比市场上传统系统的能力多十倍的热能收集能力的典型增加。该系统为南非的低成本住房计划提供了执行可能性，并可在拥有丰富太阳辐照资源的非洲大陆创造许多新的商业和就业机会。

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Development of a large-area, low-cost solar water-heating system for South Africa with a high thermal energy collection capacity

A low-cost heat-exchanger system that can be used in high-pressure/low-pressure isolated solar water-heating systems in South Africa was developed for household applications. The combination of a copper coil and electrical heater allowed for isolation of the high-pressure and low-pressure sections of the system and enabled the utilisation of large low-cost solar heat-absorber platforms that operated at low pressure with a low risk of fouling and leaking. The design comprised a copper coil heat exchanger to be installed inside a conventional geyser, to replace the normal heating element and thermostat system in a conventional commercially available household geyser. The electric heating element still supplements the system in low solar energy conditions. The circulation in the system is created by a small separate photovoltaic panel and a circulation pump. An integrated switch allows the system to alternate between conventional electrical heating and solar water-heating according to prevailing weather conditions. Current tests show that the system of 15 m2 area can be installed at a cost of approximately ZAR 10 000–12 000. The system can provide hot water at approximately 12 cents per kWh, with a total heat storage capacity of up to 10 kWh per day. This implies a saving to the customer of up to ZAR 600 per month. The accumulated saving to a household over the ten-year lifetime of the product is estimated at ZAR 200 000. As the thermal energy storage capacity of current systems as available on the local market is approximately 1 kWhr per day for a 2 m2 collector. A typical increase in thermal energy collection capacity of tenfold more than the capability of conventional systems on the market is hence achieved. The system offers implementation possibilities for South Africa’s low-cost housing schemes and can provide for creating numerous new business and job opportunities on the African continent with its abundant solar irradiation resources.

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来源期刊

Journal of Energy in Southern Africa ENERGY & FUELS-

CiteScore

3.00

自引率

0.00%

发文量

审稿时长

6 months

期刊介绍： The journal has a regional focus on southern Africa. Manuscripts that are accepted for consideration to publish in the journal must address energy issues in southern Africa or have a clear component relevant to southern Africa, including research that was set-up or designed in the region. The southern African region is considered to be constituted by the following fifteen (15) countries: Angola, Botswana, Democratic Republic of Congo, Lesotho, Malawi, Madagascar, Mauritius, Mozambique, Namibia, Seychelles, South Africa, Swaziland, Tanzania, Zambia and Zimbabwe. Within this broad field of energy research, topics of particular interest include energy efficiency, modelling, renewable energy, poverty, sustainable development, climate change mitigation, energy security, energy policy, energy governance, markets, technology and innovation.