Weather-resistance Tests for Recycled Polyethylene

2.1 Test conditions

Many types of communication facilities require long-term reliability of 10 years or more. These include communication cables, which are used for long periods of time after initial installation, so long-term reliability is a requirement. In addition, communication cables must be deployable in a variety of environments including communication buildings, underground tunnels, and outdoor settings. It is generally known that PE deteriorates under ultraviolet light and heat. Thus, when PE is intended to be used for the communication cable jackets, its long-term reliability in an outdoor environment is an important issue.

Before recycled communication cables using recycled PE for their outer jackets are deployed, they are checked to determine whether they pass standard performance tests with respect to weather resistance. However, their weather-resistance characteristics should be checked in real environments when facilities are being studied to ensure that they will exhibit high reliability and when maintenance plans are being formulated. Weather-resistance testing data is also extremely valuable for facility optimization design work, which is an ongoing endeavor. Consequently, the Technical Assistance and Support Center has been planning outdoor exposure experiments targeting recycled PE in actual environments and is currently conducting a verification experiment on the long-term reliability of cable outer jackets using recycled material. The plan for this verification experiment is outlined below. (In this article, we report on deterioration characteristics for exposure periods up to 7 years.)

2.2 Test results (for 7-year test)

This section presents the results of weather-resistance tests obtained to date for samples exposed for several periods up to 7 years. Using the pre-exposure-test characteristics of the samples for reference, we examined the changes in these characteristics after the test. Specifically, we took a sample that had been subjected to the exposure test for the specified time period and first made a visual inspection of its surface. We then evaluated the sample's rate of elongation and tensile strength by means of a tensile test.

Figure 4 plots the average value and variation (indicated by an error bar) for five samples of the relative fracture strength (as a percentage of the initial value) after each scheduled exposure period. These results show that the tensile strength of the sample PE gradually increased as the sample deteriorated through exposure. This indicates that a sample of this material hardens as a result of deterioration, which is how ordinary PE behaves when left to deteriorate.

Figure 5 plots the change in the magnitude of elongation at sample fracture (as a percentage of the initial value) for each exposure period. The vertical axis shows the relative elongation. The change over the 7-year period shows that the amount of elongation tended to decrease as deterioration progressed. We conclude that the material's hardening with deterioration made elongation increasingly difficult, which is the same behavior as shown by ordinary PE. A comparison of sample characteristics for different mixing ratios of recycled materials (0%, 50%, and 100%) showed no substantial observable differences in tensile strength or elongation retention.

Moreover, for all mixing ratios, the elongation rate of freshly produced recycled material (data not shown) sufficiently exceeded the valued specified in the domestic standard for using such material for a communication cable outer jacket (NTT-required elongation rate: 400% or greater).

The above results show that using recycled PE for communication cable outer jackets in an outdoor environment presents no problems in long-term use of at least 7 years.