TAPES

Abstract

The invention relates to a tape, comprising at least one layer comprising a. endless fiber in an total amount of at least 40 volume % as compared to the total volume of the layer and b. a thermoplastic matrix comprising one or more polyamides containing one or more aliphatic monomeric units, c. and optionally heat stabilizer, flame retardant, colorant, lubricant, mold release agent, UV stabilizer, impact modifier, laser absorbing additive as well as combinations thereof; wherein the one or more polyamides have a CH2-ratio of at least 5.5 and less than 10, calculated by identifying the number of different aliphatic monomeric units in the one or more polyamides; determining the number of CH2 groups per aliphatic monomeric unit for each of these different aliphatic monomeric units; calculating the sum of the so determined numbers of CH2 groups; dividing said sum by the number of different aliphatic monomeric units in the one or more polyamides; taking into account only the aliphatic monomeric units present in the one or more polyamides in an amount of at least 10 wt % with respect to the total weight of the one or more polyamides. The invention also relates to a vessel prepared by employing these tapes.

Claims

1. Tape, comprising at least one layer comprising a. endless fiber in an total amount of at least 40 volume % as compared to the total volume of the layer and b. a thermoplastic matrix comprising one or more polyamides containing one or more aliphatic monomeric units, c. and optionally heat stabilizer, flame retardant, colorant, lubricant, mold release agent, UV stabilizer, impact modifier, laser absorbing additive as well as combinations thereof; wherein the one or more polyamides have a CH2-ratio of at least 5.5 and less than 10, calculated by identifying the number of different aliphatic monomeric units in the one or more polyamides; determining the number of CH2 groups per aliphatic monomeric unit for each of these different aliphatic monomeric units; calculating the sum of the so determined numbers of CH2 groups; dividing said sum by the number of different aliphatic monomeric units in the one or more polyamides; taking into account only the aliphatic monomeric units present in the one or more polyamides in an amount of at least 10 wt % with respect to the total weight of the one or more polyamides.

2. Tape according to claim 1, wherein the endless fiber is chosen from the group consisting of glass fiber, carbon fiber, aramid fiber, and combinations thereof.

3. Tape according to claim 1, wherein the one or more polyamides is chosen from the group consisting of PA-410, PA-510, PA-412, PA-512, PA-610, PA-612, PA-1010, as well as blends and copolyamides thereof.

4. Tape according to claim 1, wherein the amount of endless fiber is between 10 and 60 volume % as compared to the total volume of the layer.

5. Tape according to claim 1, wherein the tape consists of one layer.

6. Tape according to claim 1, wherein the tape comprises another layer which does not comprise endless fiber, chosen from EVOH, PA-6, PA-66, PA-410, PA-6T/6I and combinations thereof and copolyamides thereof.

7. (canceled)

8. Tape according to claim 1, wherein the thickness of the tape is between 50 to 500 micron.

9. Tape according to claim 1, wherein the width of the tape is between 5 mm and 10.0 cm.

10. Tape according to claim 1, wherein the polyamide is a homopolyamide chosen from the group consisting of PA-410, PA-510, PA-412, PA512, PA-610, PA-612.

11. Tape according to claim 1, wherein the CH2 ratio is between 5.7 and 8.5.

12. Process for preparing a vessel comprising the following steps: a. Providing a support; b. providing a tape according to any of the claims above; c. Wrapping the tape around the support while consolidating the tape by heat, thereby creating a hollow body; d. Cooling the hollow body to become solid.

13. Process according to claim 11, in which the support is a mandrel and which mandrel is removed after step d.

14. Process according to claim 11, wherein before step c. another material is wrapped around the support, which material comprises EVOH, PA-6, PA-66, PA410, PA610, PA612, metal or combinations thereof.

15. Pipe, sheet material or local reinforcement, prepared by employing the tape according to claim 1.

Description

EXAMPLES

[0059] Measurements were performed on various thermoplastic matrices in order to show their suitability for use in tapes. Various homopolyamides with various CH2-ratios were tested. Results are given in Table 2.

[0060] Acid resistance test: 15 Izod bars with the polyamides as described in Table 2, were exposed to a solution of 30% H2SO4 in a petri-dish. The level of liquid was 2 mm so that the 4 mm thick bars were immersed on one side only. Separate petri-dishes were used for every take-out time (25, 50 and 100 hrs). After immersion, the bars were washed with an excess of water taking care that the upper half did not come in contact with the strong acid. After washing, the bars were dried with paper. Flexural test according to ISO178: the acid treated surface faced downward during the flexural test (non-exposed side facing up-wards).

[0061] Table 2 clearly indicates that polyamides with a CH2-ratio between 5.5 and less than 10, exhibited a combination of high acid resistance and good structural integrity. A good structural integrity is observed when the flex modulus is sufficient high in combination with a higher HDT. Examples 1 to 4 all exhibited a sufficient high flex modulus in combination with a high HDT, which makes them good candidates to be employed in a vessel according to the invention.

[0062] The most preferred polyamide being PA-410, example 1, clearly combines a high flex modulus with high HDT, which surprisingly when employed in a tape, showed a very stable long term structural integrity.

[0063] A hollow body was prepared by wrapping a tape comprising PA-6. Subsequently a tape according to the invention, comprising 65 wt % endless glass fibers and 35 wt % PA-410 was wrapped, based on the total weight of the tape around a mandrel while using heat to consolidate these wrappings. The vessel was created by attaching bosses to the hollow body, as known in the prior art. The vessel was filled with natural gas and the vessel was subjected to the Bonfire test. This test is described in ECE R110. In short, during Bonfire test, a vessel while containing gas, is subjected to 850? C. at the outside of the vessel. A vessel passes the test if the vessel does not explode, but the vessel vents the contained gas through a pressure relief device. Surprisingly, the vessel produced with a tape according to the invention, passed the Bonfire test, even though the melting temperature of PA-410 is 248? C., thus substantially lower than the heat the vessel was subjected to. This is a major achievement as this vessel allows for thermoplastic composite pressure vessels which can contain high amounts of gasses or liquids while maintaining a high safety standard and after the life time the vessel may be recycled into prime applications, which was not possible for thermoset tanks.

[0064] Surprisingly, the employment of homopolyamides provides a tape which combines high acid resistance and sufficient flex modulus in combination with a higher HDT.

TABLE-US-00002 TABLE 2 Various polyamides and results comparative comparative example example example example comparative comparative example A example B 1 2 3 4 example C example D ISO PA-6 PA-66 PA-410 PA-610 PA-612 PA-1010 PA-11 PA-12 CH2-ratio 5 5 6 7 8 9 10 11 flex modulus (GPa) ISO178 2.84 2.94 2.7 2.05 2.38 1.74 1.31 permeability CNG 0.1 0.6 @25 C. (cm3 .Math. mm/m2/day/bar) permeability H2 1.1E?16 6.7E?16 @20? C. (mol/m/s/Pa) flex modulus after 100 0.84 0.88 2.02 1.35 1.89 hrs acid exposure (GPa) retention after H2SO4 29.8 29.9 74.5 65.9 79.2 exposure (%) HDT 0.45 MPa ISO-R-75 150 215 175 140 135 110 145 135 method B HDT 1.8 MPa ISO-R-75 50 75 75 55 62 50 50 55 method A Melting temperature 222 262 248 222 218 202 189 179 (? C.)