ADVANCED TYPES OF CHECKERWORK OF REGENERATIVE HEAT EXCHANGERS FOR GLASS FURNACES

Integrated Technologies and Energy Saving Pub Date : 2021-07-06 DOI:10.20998/2078-5364.2021.1.01

O. Koshelnik, S. Hoisan

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Abstract

One of the ways to increase glass furnaces energy efficiency is to apply heat exchangers for flue gases thermal potential utilization. Flue gases losses is up to 25-40 % of the total amount of heat supplied in the furnace. These losses are influences by such factors as fuel type, furnace and burners design and manufactured product type. Regenerative heat exchangers with various types of heat storage packing is more efficient for high-power furnaces. Such types of regenerator checkerwork as Cowper checkerwork, two types of Siemens checkerwork, Lichte checkerwork and combined checkerwork have already been sufficiently researched, successfully applied and widely used for glass furnaces of various designs. All of its are made of standard refractory bricks. Basket checkerwork and cruciform checkerwork that are made of fused-cast molded refractory materials have been widely used recently as well. Further improvement of regenerative heat exchangers thermal efficiency only by replacing the checkerwork does not seem possible unless their size being increased. But this enlarging is not always realizable during the modernization of existing furnaces. From this point of view heat storage elements with a phase transition, where metal salts and their mixtures are used as a fusible agent look promising for glass furnaces. These elements can accumulate additional amount of heat due to phase transition, which allows to increase significantly heat exchanger thermal rating without its size and operating conditions changing. However, it is necessary to carry out additional studies of this type of checkerwork dealing with analysis of complex unsteady heat exchange processes in regenerators and selection of appropriate materials that satisfy the operating conditions of regenerative heat exchangers so that the checkerwork can be widely used for glass furnaces.

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玻璃炉蓄热式换热器的先进型检查

采用热交换器对烟气热势进行利用是提高玻璃炉能源效率的途径之一。烟气损失高达炉内供热总量的25- 40%。这些损失受燃料类型、炉子和燃烧器设计以及制造产品类型等因素的影响。蓄热式换热器采用不同类型的蓄热填料，对大功率炉效率更高。古柏方格、两种西门子方格、利希特方格和组合式方格等蓄热式方格已经在各种设计的玻璃炉上得到了充分的研究和成功的应用。全部由标准耐火砖制成。采用熔铸成型耐火材料制成的篮形格子和十字形格子近年来也得到了广泛的应用。进一步提高蓄热式换热器的热效率，仅通过更换检查机构似乎是不可能的，除非他们的尺寸增加。但是，在现有熔炉的现代化过程中，这种扩大并不总是可以实现的。从这个角度来看，具有相变的储热元件，其中金属盐及其混合物被用作易熔剂，看起来很有希望用于玻璃炉。由于相变，这些元件可以积累额外的热量，这可以在不改变其尺寸和操作条件的情况下显着增加热交换器的热额定值。然而，有必要对这种格子进行进一步的研究，分析蓄热器中复杂的非定常换热过程，选择满足蓄热式换热器工作条件的合适材料，使这种格子能广泛应用于玻璃炉。

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Integrated Technologies and Energy Saving

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