Effects of Temperature and Moisture Content on Young’s Modulus in Glass Fiber Reinforced Polyamide

Abstract: This thesis was made in cooperation with Roxtec. Roxtec specialises in cable sealingsolutions and are world leading in their area. In many of Roxtec’s products steel isused in the frame holding the sealing rubber. To lower Roxtec’s environmental foot-print plastic would be used instead in the frames if possible, more specific polyamide6.6 with 25% glass fiber reinforcement (PA66GF25). Polyamide is affected to agreater extent by temperature and humidity than steel and therefore poses a greaterrisk when considering the sealing capability in harsh conditions. The purpose of thisthesis is therefore to investigate the effects on the Young’s modulus by temperatureand relative humidity, which both correlate to moisture content in the plastic. Theintended temperature and moisture saturation interval are -40◦C to 80◦C and 0% to100% moisture saturation respectively. Tensile test samples were made through machining samples from existing productsand conditioning them to desired moisture content. With the use of tensile testingthe Young’s modulus could be determined for a number of combinations of temper-ature and moisture content. From this data an approximated polynomial surfaceof the Young’s modulus could be produced. The conditioning of the test piecescould be accelerated by submersion in heated water, decreasing conditioning timeto less than two days. The approximation of the Young’s modulus function couldbe done using polynomial approximation. The resulting polynomial for the positivetemperatures was of the third order dependant of the two variables moisture con-tent and temperature. For the negative temperatures a single variable polynomialwas approximated due to only one moisture content being tested for. To ensure thevalidity of the model each test combination consisted of three individual tensile testof which an average was calculated. The approximated function was then comparedto a data sheet value for a certain moisture content and temperature. From theresulting surface approximation of the Young’s modulus in positive temperatures itcan be deduced that PA66GF25 is more greatly affected by moisture content thantemperature. Especially at low levels of moisture content where the rise in Young’smodulus is exponential while more linear at higher moisture contents. The maximumand minimum Young’s modulus was found to be 8 GPa and 2.7 GPa respectively.The negative temperature approximation was restricted to one moisture content andtherefore resulted in a graph. The behaviour of this graph was likely a result of icein the material as similarities to a study regarding the mechanical properties of icewas found.