heat loss due to combustibles in refuse

简明释义

机械不完全燃烧热损失

英英释义

例句

1.The facility implemented new technologies to reduce heat loss due to combustibles in refuse during incineration.

该设施实施了新技术，以减少焚烧过程中由于垃圾中的可燃物造成的热损失。

2.Understanding heat loss due to combustibles in refuse is essential for improving energy efficiency in waste management systems.

理解由于垃圾中的可燃物造成的热损失对于提高废物管理系统的能效至关重要。

3.The report highlighted the significant heat loss due to combustibles in refuse that can affect overall energy recovery.

报告强调了可能影响整体能量回收的显著由于垃圾中的可燃物造成的热损失。

4.The engineers calculated the heat loss due to combustibles in refuse when designing the waste-to-energy plant.

工程师在设计垃圾发电厂时计算了由于垃圾中的可燃物造成的热损失。

5.To minimize heat loss due to combustibles in refuse, we need to optimize the combustion process.

为了最小化由于垃圾中的可燃物造成的热损失，我们需要优化燃烧过程。

作文

In modern waste management, the efficiency of energy recovery from refuse is a critical aspect that many industries focus on. One significant factor that affects this efficiency is heat loss due to combustibles in refuse. This term refers to the energy lost when combustible materials within the waste are incinerated but do not fully contribute to energy recovery. Understanding this concept is essential for optimizing waste-to-energy processes and improving overall energy efficiency.When waste is incinerated, the primary goal is to convert it into energy. However, not all of the combustible materials in the refuse can be burned completely or efficiently. Factors such as moisture content, the chemical composition of the waste, and the operational conditions of the incineration process play a crucial role in determining how much energy is recovered. Any unburned material represents a heat loss due to combustibles in refuse, which signifies wasted potential energy that could have been harnessed.For instance, if a waste stream contains a high percentage of wet organic materials, the energy required to evaporate the moisture can significantly reduce the overall combustion efficiency. Consequently, more energy is expended on drying out these materials rather than converting them into usable energy. This inefficiency not only leads to heat loss due to combustibles in refuse but also increases operational costs for waste management facilities.Moreover, the presence of certain types of plastics and other non-biodegradable materials can further complicate the incineration process. These materials may release harmful pollutants when burned, requiring additional filtering and treatment processes. As a result, the energy that could be recovered from the combustion of these combustibles is diminished, contributing to heat loss due to combustibles in refuse and reducing the overall effectiveness of waste-to-energy technologies.To minimize heat loss due to combustibles in refuse, waste management facilities can implement various strategies. One approach is to enhance the sorting of waste before incineration. By separating high-value combustible materials from those that are less efficient to burn, facilities can increase the quality of the feedstock entering the incinerator. This practice ensures that more energy can be extracted during the combustion process, thereby reducing heat losses.Additionally, advancements in technology, such as improved incineration systems that allow for better temperature control and oxygen supply, can help maximize combustion efficiency. These innovations can lead to a more complete combustion of the refuse, thus reducing heat loss due to combustibles in refuse and increasing the overall energy output.In conclusion, understanding heat loss due to combustibles in refuse is vital for enhancing the efficiency of waste-to-energy processes. By recognizing the factors that contribute to this heat loss and implementing strategies to mitigate it, waste management facilities can improve their energy recovery rates and contribute to more sustainable waste management practices. This not only benefits the environment by reducing landfill use but also supports the transition towards renewable energy sources, making it an essential consideration for the future of waste management.

在现代废物管理中，从垃圾中高效回收能源是许多行业关注的关键方面。影响这一效率的一个重要因素是由于垃圾中可燃物造成的热量损失。这个术语指的是当垃圾中的可燃材料被焚烧但未能完全转化为能源时所损失的能量。理解这个概念对于优化垃圾转能源过程和提高整体能源效率至关重要。当垃圾被焚烧时，主要目标是将其转化为能源。然而，并非所有的垃圾中可燃材料都能被完全或高效地燃烧。湿度含量、垃圾的化学成分以及焚烧过程的操作条件等因素在决定能量回收量方面起着关键作用。任何未燃烧的材料都代表了由于垃圾中可燃物造成的热量损失，这意味着本可以利用的潜在能量被浪费了。例如，如果废物流中含有较高比例的湿有机材料，那么蒸发水分所需的能量会显著降低整体燃烧效率。因此，在干燥这些材料上消耗的能量会比将其转化为可用能量的能量更多。这种低效率不仅导致由于垃圾中可燃物造成的热量损失，而且还增加了废物管理设施的运营成本。此外，某些类型的塑料和其他不可生物降解材料的存在可能进一步复杂化焚烧过程。这些材料在燃烧时可能释放有害污染物，要求额外的过滤和处理工艺。因此，从这些可燃物的燃烧中可以回收的能量减少，从而导致由于垃圾中可燃物造成的热量损失，降低了垃圾转能源技术的整体有效性。为了最小化由于垃圾中可燃物造成的热量损失，废物管理设施可以实施各种策略。一种方法是在焚烧前增强垃圾的分类。通过将高价值的可燃材料与那些燃烧效率较低的材料分开，设施可以提高进入焚烧炉的原料质量。这种做法确保在燃烧过程中能够提取更多的能量，从而减少热损失。此外，技术的进步，例如改进的焚烧系统，可以实现更好的温度控制和氧气供应，从而帮助最大化燃烧效率。这些创新可以导致垃圾的更完全燃烧，从而减少由于垃圾中可燃物造成的热量损失，提高整体能量输出。总之，理解由于垃圾中可燃物造成的热量损失对于提高垃圾转能源过程的效率至关重要。通过认识到导致这种热损失的因素并实施缓解策略，废物管理设施可以提高其能量回收率，并促进更可持续的废物管理实践。这不仅通过减少填埋场使用而有利于环境，而且支持向可再生能源源的过渡，使其成为废物管理未来的重要考虑。