微波烧结是一个非常复杂的过程。
采用微波烧结新技术研究了纳米金属陶瓷材料的烧结工艺与性能。
The technology and property of nanometer cermet is studied with new microwave sintering technology.
微波烧结作为一种陶瓷材料烧结的新方法,近年来得到飞速发展。
As a new method of ceramic material sintering, microwave sintering has been improved rapidly in recent years.
并通过试验,用微波炉模拟微波烧结腔体测得温度数据,建立模型。
In experiment, microwave oven is used to simulate microwave sintering cavity, then temperature data are gained and model is established.
微波能是一种清洁型的新型能源,利用微波的热效应进行磁铁精矿微波烧结是一项全新的课题。
Microwave energy is a clean energy, and microwave sintering of magnetite concentrates is a new subject by microwave heating effect.
介绍了微波烧结原理与特点、微波烧结设备与工艺参数以及微波烧结技术在陶瓷材料领域中的应用和所取得的研究成果。
Principles, characteristics and equipment of microwave sintering are introduced for ceramics. This paper introduced the coefficient of microwave sintering and its application technic.
材料的介电常数和品质因数随着微波烧结温度的提高而增大,对应数值分别比传统烧结方式提高17.5%和14.3%左右。
The value of sr and Q of ZST increased with the increasing of sintering temperature, and the corresponded value increase 17.5% and 14.3% respectively, compared with electrical-thermal sintering.
本文在分析了微波烧结温度工作过程的特性和系统的特殊之处后,提出了计算机两级控制系统的结构对微波烧结温度进行了有效的控制。
After analyzing the feature of microwave sintering and the specialty of this system, we propose the computer two-stage structure to realize the reliable control of microwave sintering temperature.
选用微波烧结新工艺,对ZTA陶瓷力学性能进行了研究,获得了较传统烧结工艺优良的陶瓷力学强度和断裂韧性。同时,新工艺改善了陶瓷体的显微结构。
Microwave Sintering, as a new aspect on the study of ZTA ceramics, improves the bending strength and the fracture toughness KIC of ZTA and the micro structure.
本文主要研究微波测水技术在烧结混合料上的应用情况。
This research mainly studies the application of microwave moisture measuring technique on sinter mixture.
优化低温烧结微波介质陶瓷介电性能。
Optimize the dielectric properties of low temperature sintered microwave dielectric ceramics.
试验的结果表明,微波在线测水系统在烧结混合料水分测量上具有应用推广价值。
The result of the tests infers that the microwave on-line moisture measurement system is applicable for sinter blend and worth being extended.
结果表明,利用微波加热可以顺利实现陶瓷材料之间的同时烧结与连接。
It was found that simultaneous sintering and joining could be completed successfully by microwave.
从麦克斯韦方程组出发,分析了微波在块体金属中的传播行为,说明微波不能与块体金属耦合并烧结的原因。
From Maxwell's equation, the transmitting behavior in bulk metal and the reason why microwave does not effectively couple with bulk metal are analyzed.
实验表明:通过合理的保温结构和工艺控制,可实现高稳定性和重复性的微波快速烧结。
The experimental results show that a fast ceramic sintering with high stability and repetition could be realized through suitable control of heating profile and improving of hybrid heating structure.
为满足多层微波元件低温烧结的需求,必须降低微波介质陶瓷的烧结温度。
To lower temperature sintering is desired for the fabrication of multiplayer microwave ceramics.
将上述组份经过称量、混合球磨、煅烧、粉碎、造粒、成型和烧结等固相反应工序烧制成微波介质陶瓷。
It is prepared through mixing the materials, ball milling, calcining, crushing, pelletizing, forming, sintering and other steps.
结果表明,微波等离子体烧结技术与常规法相比,其烧结时间明显缩短,性能有所改善。
The result indicates that the microwave plasma sintering can short the sintering time and improve the properties of CaZrO3 ceramics as compared with the routine methods.
本文简要介绍了四类微波介质陶瓷的研究现状,着重评述了微波介质陶瓷在低温烧结方面的最新研究进展。
Present research status in the four sorts materials are introduced. In this paper, recent progress in low-temperature firing in MWDC is reviewed in detail.
钛酸锌微波介质陶瓷因其优异的介电性能、较低的烧结温度,而被广泛应用于制备银、铜电极共烧中温低介微波材料中。
As ZnTiO3 has the outstanding dielectric property and low sintering temperature, it has been mixed with Ag, Cu, etc. to prepare electrodes at relatively low sintering temperature.
钛酸锌微波介质陶瓷因其优异的介电性能、较低的烧结温度,而被广泛应用于制备银、铜电极共烧中温低介微波材料中。
As ZnTiO3 has the outstanding dielectric property and low sintering temperature, it has been mixed with Ag, Cu, etc. to prepare electrodes at relatively low sintering temperature.
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