新型弹性体材料,适用于无限水深的极端温度下的海底绝热应用

Adam C Jackson, Rodrigo Diaz, Heidi Svalund, Raymond Hansen, Grethe Hartviksen
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引用次数: 0

摘要

橡胶基系统已经在海底绝热中使用了多年,并且证明了其可靠性和成本效益。多年来,配方已经发生了变化,在湿热环境中,将最高使用温度向上推至160至180°C。直到最近,还需要高温和压力容器(高压灭菌器)来进行硫化。这限制了这种系统的广泛使用。最近的变化已经消除了对高压灭菌器的需要,但是仍然需要高温硫化。一种新的配方已经开发出来以解决这些缺点,因此这类材料可以有更广泛的用途。这种新材料采用了一种独特的混合材料。该材料不含可水解基团,可在- 40°C至180°C的空气和湿热环境中连续工作,并保持其弹性和柔韧性;因此可以在高温和低温系统中使用。该配方不包括中空玻璃微球的使用,并且相应地没有水深限制。一种新的,高度可靠的硫化化学允许稳定的应用延迟时间,硫化温度降低到50°C。这使得海底采油树、阀门、歧管等的手动快速应用和同时硫化成为可能。该材料自凝聚,在温和的压力下合并,可以在高厚度下应用。由于基材具有固有的低导热性,因此不需要玻璃基填料。该材料可以很好地粘附在涂漆或底漆的表面上,也可以粘附在海上绝热行业中常用的许多其他材料上。这种双组分材料可以在现场方便地组合在一起,减少了运输过程中对冷藏的需求,简化了动员物流,并使用简单的手动工具进行应用。挤压型材可以直接用于复杂的结构或组合成片,便于在更规则的形状上应用,以优化应用率。模具不需要的应用,降低工程和制造成本,同时也缩短动员时间。该系统已通过ISO 12736的广泛认证,可在180°C下连续使用。本文将详细介绍开发项目的重要方面以及资格测试的结果。
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Novel Elastomer Materials for Extreme Temperature Operation in Subsea Thermal Insulation Applications at Unlimited Water Depth
Rubber based systems have been used in subsea thermal insulation for many years and have proven themselves to be reliable and cost efficient. Formulations have been changed over the years, pressing the maximum usage temperature upwards and into the realm of 160 to180°C in a hot-wet environment. Until recently there was a need for high temperature along with pressure vessels (autoclaves) for vulcanisation. This has limited the widespread use of such systems. Recent changes have eliminated the need for autoclaves, however the high temperature vulcanisation hasstill been required. A novel formulation has been developed to address these shortcomings, so that this class of materials could have wider use. This new material employs freely available materials in a unique blend. The material contains no hydrolysable groups and can operate from −40°C to 180°C continuously in air and in a hot-wet environment and retains its resilience and flexibility; and thus opening for use in both high and low temperature systems. The formulation does not include the use of hollow glass microspheres and is, correspondingly, without water depth limitations. A new, highly reliable vulcanisation chemistry allows for a stable latency time for application, with vulcanisation temperatures reduced to 50°C. This allows for rapid hand application and simultaneous vulcanisation on subsea trees, valves, manifolds, etc. The material is self-agglomerating, merging under gentle pressure, and can be applied at high thickness. As the base material has an intrinsically low thermal conductivity, glass-based fillers are not needed. The material adheres well to painted or primed surfaces and to many other materials typically used in the offshore thermal insulation industry. The 2-component material is conveniently combined on site, reducing the need for refrigeration during transport and easing mobilisation logistics and is applied using simple hand tools. Extruded profiles can be used directly on complex structures or combined into sheets for ease of application on more regular shapes in order to optimise application rates. Moulds are not required for application, reducing engineering and fabrication cost, while also shortening mobilisation time. The system has been extensively qualified according to ISO 12736 for continuous use at 180°C. This paper will detail important aspects of the development project along with the results of the qualification testing.
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