The chemical binders used to make sand molds and cores thermally decompose and release gas when subjected to the high temperature conditions in sand casting processes. Computational models that predict the evolution of the binder gas are being introduced into casting simulations in order to better predict and eliminate gas defects in metal castings. These models require knowledge of the evolved binder gas mass and molecular weight as a function of temperature, but available gas evolution data are limited. In the present study, the mass and molecular weight of gas evolved from PUNB bonded sand are measured as a function of temperature for use with binder gas models. Thermogravimetric analysis of bonded sand is employed to measure the binder gas mass evolution as a function of temperature for heating rates experienced in molds and cores during casting. The volume and pressure of gas evolved from bonded sand are measured as a function of temperature in a specially designed quartz manometer during heating and cooling in a furnace. The results from these experiments are combined with the ideal gas law to determine the binder gas molecular weight as a function of temperature. Thermogravimetric analysis reveals that the PUNB binder significantly decomposes when heated to elevated temperatures, and the PUNB binder gas mass evolution is not strongly influenced by heating rate. During heating of PUNB bonded sand at a rate of 2°C/min, the binder gas molecular weight rapidly decreases from 375 g/mol at 115°C to 99.8 g/mol at 200°C. The molecular weight is relatively constant until 270°C, after which it decreases to 47.7 g/mol at 550°C. The molecular weight then steeply decreases to 30.3 g/mol at 585°C and then steeply increases to 47.2 g/mol at 630°C, where it remains constant until 750°C. Above 750°C, the binder gas molecular weight gradually decreases to 33.3 g/mol at 898°C. The present measurements are consistent with the molecular weights calculated using the binder gas composition data from previous studies. The binder gas is composed of incondensable gases above 709°C, and the binder gas partially condenses during cooling at 165°C if the bonded sand is previously heated below 507°C.
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机译:在砂型铸造工艺中经受高温条件时,用于制造砂型和型芯的化学粘合剂会热分解并释放出气体。为了更好地预测和消除金属铸件中的气体缺陷,可将预测粘结剂气体逸出的计算模型引入铸造模拟中。这些模型需要了解随温度变化的释放出的结合气质量和分子量,但可用的气体逸出数据有限。在本研究中,测量了从PUNB粘结砂中逸出的气体的质量和分子量,并将其作为温度的函数,用于结合气体模型。结合砂的热重分析用于测量铸造过程中铸模和型芯中所经历的加热速率随温度变化的粘结剂气体质量演变。在炉子中加热和冷却期间,由专门设计的石英压力计测量从粘结砂中散发出的气体的体积和压力与温度的关系。将这些实验的结果与理想气体定律相结合,以确定结合气体分子量随温度的变化。热重分析表明,加热到高温时,PUNB粘合剂会明显分解,并且加热速率不会强烈影响PUNB粘合剂气体的逸出量。在以2°C / min的速度加热PUNB粘结砂的过程中,粘结剂气体的分子量从115°C的375 g / mol快速降低到200°C的99.8 g / mol。直到270℃为止,分子量相对恒定,此后在550℃下降低至47.7g / mol。然后,分子量在585℃下急剧降低至30.3g / mol,然后在630℃下急剧升高至47.2g / mol,在此保持恒定直至750℃。高于750°C时,粘合剂气体分子量在898°C时逐渐降低至33.3 g / mol。当前的测量结果与使用先前研究的结合气成分数据计算出的分子量相符。结合剂气体由高于709°C的不凝气体组成,如果预先将结合砂加热到507°C以下,则结合剂气体在165°C冷却期间会部分冷凝。
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