hydrokinetic
简明释义
英[ˌhaɪdrəʊkaɪˈnetɪk]美[ˌhaɪdrəkɪˈnetɪk]
adj. 流体动力的;流体动力学的
英英释义
Relating to the motion of fluids, especially water, and the energy derived from this motion. | 与流体(尤其是水)的运动及由这种运动产生的能量相关的。 |
单词用法
水动能涡轮 | |
水动能系统 | |
水动能设备 | |
利用水动能 | |
产生水动能 | |
开发水动能技术 |
同义词
反义词
| 静态的 | 系统的静态能量被测量。 | ||
| 不动的 | 尽管有风,那个不动的物体依然没有移动。 |
例句
1.YSGG laser is a laser-powered hydrokinetic system of new generation, which is now being gradually searched and applied for curing caries.
YSGG激光是新一代水动力生物激光系统,在龋病治疗中的应用正不断深入。
2.YSGG laser is a laser-powered hydrokinetic system of new generation, which is now being gradually searched and applied for curing caries.
YSGG激光是新一代水动力生物激光系统,在龋病治疗中的应用正不断深入。
3.The hydrokinetic 水动力的 devices can be installed in existing waterways to generate clean energy.
这些
4.Researchers are exploring hydrokinetic 水动力的 energy as a sustainable alternative to fossil fuels.
研究人员正在探索
5.Many coastal cities are investing in hydrokinetic 水动力的 technology to power their infrastructure.
许多沿海城市正在投资
6.The new park features a hydrokinetic 水动力的 sculpture that generates energy from flowing water.
这个新公园有一个
7.The hydrokinetic 水动力的 turbine can harness the energy of rivers without the need for dams.
这个
作文
In recent years, the search for sustainable energy sources has become increasingly urgent. One of the most promising avenues is the development of hydrokinetic energy systems. Hydrokinetic energy refers to the energy derived from the movement of water, particularly in rivers, tidal flows, and ocean currents. Unlike traditional hydroelectric power, which relies on large dams and reservoirs, hydrokinetic systems harness the kinetic energy of flowing water without the need for significant infrastructure changes. This makes them an attractive option for both environmental sustainability and energy efficiency.The implementation of hydrokinetic technology can have profound implications for energy production. For instance, small-scale hydrokinetic turbines can be installed in rivers or streams, generating electricity for local communities without disrupting the ecosystem. These systems not only provide a renewable source of energy but also minimize the impact on fish migration and water quality compared to traditional hydroelectric dams. As a result, hydrokinetic energy presents a viable alternative for regions where conventional energy sources are limited or environmentally damaging.Moreover, the potential for hydrokinetic energy extends beyond freshwater systems. Coastal areas can benefit significantly from tidal and wave energy, both of which are forms of hydrokinetic energy. Tidal energy, generated from the gravitational pull of the moon and sun, is highly predictable and can provide a stable energy supply. Wave energy, on the other hand, captures the energy produced by surface waves and can be harnessed even in relatively low-energy conditions. Together, these forms of hydrokinetic energy can contribute to a diversified and resilient energy grid.Despite its advantages, the adoption of hydrokinetic technology faces several challenges. One major concern is the initial cost of installation and maintenance. While hydrokinetic systems generally require less infrastructure than traditional hydroelectric plants, the technology is still in its infancy, and costs can be prohibitive for some communities. Additionally, there are regulatory hurdles to overcome, as many waterways are subject to strict environmental protections. Navigating these regulations while promoting hydrokinetic projects requires collaboration between governments, environmental organizations, and private companies.Another challenge is the need for further research and development. Although the principles of hydrokinetic energy are well understood, optimizing the technology for efficiency and durability in various water conditions remains a priority. Innovations in materials and turbine design could enhance energy capture and reduce wear and tear, making hydrokinetic systems more viable for widespread use.In conclusion, hydrokinetic energy represents a promising frontier in the quest for sustainable energy solutions. By capitalizing on the natural flow of water, we can generate clean, renewable energy while minimizing environmental impact. As technology advances and more communities embrace hydrokinetic systems, we may find ourselves moving closer to a future powered by the very forces of nature that surround us. The transition to a more sustainable energy paradigm will require innovation, investment, and cooperation, but the potential benefits of hydrokinetic energy are too significant to ignore.
近年来,寻找可持续能源来源变得越来越紧迫。其中一个最有前景的方向是开发水动力能源系统。水动力能源是指从水流中获取的能量,尤其是在河流、潮流和洋流中。与传统的水电相比,后者依赖于大型水坝和水库,水动力系统利用流动水的动能,而无需进行重大基础设施改动。这使它们成为环境可持续性和能源效率的一个吸引人的选择。实施水动力技术可能对能源生产产生深远的影响。例如,小型水动力涡轮机可以安装在河流或溪流中,为当地社区发电,而不会破坏生态系统。这些系统不仅提供了可再生能源,还最大限度地减少了对鱼类迁徙和水质的影响,相比于传统的水电大坝,水动力能源呈现出一种可行的替代方案,尤其是在常规能源来源有限或对环境造成损害的地区。此外,水动力能源的潜力超越了淡水系统。沿海地区可以显著受益于潮汐和波浪能,这两者都是水动力能源的一种形式。潮汐能是由月球和太阳的引力产生的,具有高度的可预测性,可以提供稳定的能源供应。另一方面,波浪能捕捉表面波产生的能量,即使在相对低能量的条件下也能被利用。这些形式的水动力能源可以共同为多样化和韧性的能源网络做出贡献。尽管具有优点,水动力技术的采用仍面临一些挑战。一个主要问题是安装和维护的初始成本。虽然水动力系统通常需要的基础设施少于传统的水电站,但该技术仍处于初级阶段,成本对一些社区来说可能是负担。此外,许多水道受到严格的环境保护法规的约束,因此还存在监管障碍。在推动水动力项目的同时,如何在这些法规中找到平衡,需要政府、环保组织和私营公司之间的合作。另一个挑战是需要进一步的研究和开发。尽管水动力能源的原理已经得到很好的理解,但在各种水条件下优化技术的效率和耐久性仍然是一个优先事项。材料和涡轮设计的创新可以提高能量捕获能力并减少磨损,使水动力系统更具广泛使用的可行性。总之,水动力能源代表了在追求可持续能源解决方案方面的一个有前景的前沿。通过利用水的自然流动,我们可以生成清洁、可再生的能源,同时最大限度地减少对环境的影响。随着技术的进步和更多社区接受水动力系统,我们可能会发现自己更接近一个由周围自然力量驱动的未来。向更可持续能源范式的转变将需要创新、投资和合作,但水动力能源的潜在好处是不可忽视的。
