意义和目的
4.1 在运输和施工过程中，管道涂层的损坏几乎是不可避免的. Breaking or peeling of the pipe coating may expose the pipe to possible corrosion because after the pipe is installed underground, the surrounding soil will be moist and will constitute effective electrolytes. The cathodic protection potential applied may cause the coating to loosen, starting from the holiday edge. Spontaneous holidays may also be caused by this potential. 通常, external pipe coatings coated on pipes carrying thermal media (油, gas) are exposed to high temperatures inside the pipe and low temperatures outside, and are subject to temperature gradients. The heat flux is directed from the metal (基质) to the coating. The test method provides accelerated conditions for cathodic stripping that occurs under simulated heating and provides a measurement of the resistance of the coating to such effects.

4.2 The effect of the test will be evaluated by physical examination and monitoring the current consumed by the test sample. Usually there is no correlation between the two evaluation methods, but both are significant. The physical examination involves assessing the effective contact of the coating with the metal surface based on the observed difference in relative adhesive bonding. It is often found that the cathodic debonding region propagates from the region where adhesion is zero to the region where adhesion has reached the original level. There may also be intermediate areas of reduced adhesion.

4.3 Assumptions related to the test results include:

美国材料试验协会D 6676-2021 “内热法测定管道内壁涂层加热时的阴极剥离性”

4.3.1 The maximum adhesion or bonding force is found in the coating not immersed in the test liquid, 和

4.3.2 The reduced adhesion in the immersion test area is the result of cathode debonding.

4.4 On a comparative basis, the ability to resist stripping is of professional quality, but stripping in this test method is not necessarily an unfavourable indication of coating performance. The advantage of this test method is that all the dielectric type coatings that are now commonly used destick to some extent, thus providing a way to compare one coating with another.

4.5 The current flow in the test unit is a relative indicator of the extent of the area requiring corrosion protection; 然而, the current densities present in this test are much greater than those normally required for cathodes protection in natural inland soil environments.

4.6 Test voltages higher than the recommended voltage may cause chlorine gas formation. Subsequent chemical effects on the coating may call into question the interpretation of the test results. A filter tube with a sintered disk (see test method G95) or a sand layer (40 mesh) on the coated surface can reduce this effect.

美国材料试验协会D 6676-2021 “内热法测定管道内壁涂层加热时的阴极剥离性”

范围
1.1 This test method describes an accelerated procedure for determining the comparative characteristics of a coating system applied to the exterior of a steel pipe to prevent or mitigate corrosion that may occur underground or in water where the pipe carries a heating medium and is under cathodic protection. The test method is intended for use on samples of coated tubes, or specimens cut from coated tubes or plate parts, and is applicable to such samples when the coating has an electrical barrier function.

1.2 The test method is designed to simulate the exposure of the outer coating to the high temperature inside the pipe and the ambient temperature outside, thus being affected by the temperature gradient. If high temperature is required but no temperature gradient is available, see Test Method G42.

1.3 以 SI 单位或英寸-磅单位表示的值应单独视为标准值. 每个系统中指定的值不一定相同; 所以, 确保符合标准, 每个系统应相互独立使用，两个系统的值不应组合.

美国材料试验协会D 6676-2021 “内热法测定管道内壁涂层加热时的阴极剥离性”

1.4 本标准并非旨在解决所有安全问题, 如果有的话, 与其使用相关. 本标准的使用者有责任建立适当的安全机制, 健康和环境实践，并在使用前确定监管限制的适用性.

1.5 本国际标准是根据《关于制定国际标准的原则的决定》中确立的国际公认的标准化原则制定的, 世界贸易组织贸易技术壁垒委员会发布的指南和建议.