Effect of mineral filler additives on flammability, processing and use of silicone-based ceramifiable composites

High temperature vulcanizable silicone rubber (HTV) containing 0.07% mol/mol of vinyl groups, produced by Polish Silicones Ltd. (Poland), reinforced with Aerosil 200 fumed silica (BET specific surface area 175–225 m²/g; mass loss on drying ≤1.5%), originated from Evonik Industries (Germany) was used as an elastomer base for the research. Fluxing agent (A 2120), a glassy frit, consist of 7.3% wt of CaO, 25.0% wt of Na₂O, 2.1% wt of K₂O, 4.2% wt of Al₂O₃, and 61.4% wt of SiO₂, with softening point temperature of T _s = 480 °C (particle size on sieve ≤63 µm), originated from Reimbold & Strick GmbH (Germany) was used. Natural kaolin KOM (particle size distribution D₉₀ = 4.2 µm, D₅₀ = 1.3 µm and D₁₀ = 0.2 µm; BET specific surface area 13 m²/g) was originated form Surmin–Kaolin mine (Poland), which is a part of Quarzwerke GmbH group (Germany). Calcined kaolin (Polestar 200R; particle size distribution >10 µm = 10% max, <2 µm = 44% min; BET specific surface area 8.5 m²/g) was purchased form Imerys Minerals Ltd (France). Mica–phlogopite (PW 30; particle size distribution <150 µm = 99–100%, <45 µm = 90% min, D₅₀ = 18 µm) was purchased from LKAB Minerals (Sweden). Aluminum hydroxide (Martinal OL-107 LEO; particle size distribution D₅₀ = 1.6–1.9 µm; BET specific surface area 6–8 m²/g) was originated from Martinswerk GmbH (Germany), which is a part of Albemarle Corporation (USA). Calcium-based—technical grade minerals mix (CbMix) consists of CaO (6.26 wt%), CaCO₃ (26.18 wt%) and Ca(OH)₂ (67.56 wt%) calculated from thermogravimetric analysis (Fig. 6a), (particle size distribution D₅₀ = 3.5–4.0 µm) was purchased from Mercury HM (Poland). Calcium carbonate—technical grade (particle size distribution D₅₀ = 1.5–2.0 µm), was obtained from Minerał Ltd mine (Poland). Titanium oxide (anatase; particle size distribution ≤45 µm) was purchased form Sigma Aldrich (USA). 50% wt. paste of bis(2,4-dichlorobenzoyl) peroxide, used for curing of the studied composite mixes was purchased from Novichem (Poland). All the components were used as received.

Surface free energy of the mineral fillers was measured using Krűss K100 tensiometer (Germany) operating in sorption mode with polar (methanol) and non-polar (hexane) liquids (Table 1). Thermogravimetry (TG) performed along with differential scanning calorimetry (DSC) analysis of the mineral fillers was done by means of Netzsch SPA 449 F3 device (Germany), with heating rate of 10 °C/min, under air atmosphere.

Silicone rubber-based mixes (Table 2) were prepared by Brabender-Plasticorder laboratory micromixer (Germany), with the rotor operational speed of 20 rpm, during the components incorporation (5 min) and of 60 rpm speed during mixes homogenization (10 min).

Kinetic of vulcanization of the mixes was measured by means of WG-05 vulcameter (Poland) at 130 °C, directly after mixes preparation and for comparison after a week of conditioning at storage temperature. Mechanical properties of the samples vulcanized directly after preparation were studied by means of Zwick-Roell 1435 instrument (Germany). Stress at 100% (SE100), 200% (SE200) and 300% (SE300) of elongation was determined along with elongation at break (Eb) and tensile strength (TS) of the vulcanizates. Flame retardancy of the composites was determined by oxygen index measurement (OI) according to the PN-ISO 4589-2 standard. Moreover, cone calorimetry measurements were done by means of Fire Testing Technology Ltd. calorimeter (UK) operating with heating source of 35 kW/m² placed 25 mm from the samples surface. Smoke intensity during burning was calculated according to the PN-91/K-02501 standard, in which intensity of defined lamp light beam transmittance intensity, during 4 min of burning is calculated as lx • 240 s. This test divides materials into three groups: exhibiting low intensity of smoking D1 >18,000 (l×s), medium intensity of smoking 9000 (l×s) <D2 ≤18,000 (l×s) and high intensity of smoking D3 ≤9000 (l×s).

Micromorphology of the composite samples was examined before and after ceramification by means of scanning electron microscopy (SEM) Nova Nano 200 FEI (United Kingdom).

Qualitative and quantitative analysis of the ceramified samples containing calcium-based fillers (CAO and CACO) was performed by means of X-ray scattering diffractometer—Empyrean Panalytical B. V. (The Netherlands) operating with 60 kV source voltage. Qualitative determination of crystalline phases was done utilizing ICDD database (pseudowollastonite 98-002-6553; b-quartz 98-008-9281 a-quartz 98-007-7681; CaO 98-002-6959; albite 98-003-4917; parawollastonite 98-003-0884; cristobalite 98-016-2660; tridymite 98-009-4090). Quantitative analyses were performed by means of the Rietveld refinement procedure.

The samples of the composites vulcanized using cylindrically shaped mold of 8 mm of height and 16 mm of diameter were thermally treated by PWP Prod-Ryn laboratory furnace (Poland), being subjected to heating form room temperature to 1050 °C (heating rate of ~5 °C/min) and afterwards conditioned at the maximum temperature for 30 min. Subsequently, ceramified samples were left to cool down to room temperature. Compression strength of ceramified composites was determined by means of Zwick-Roell Z 2.5 instrument (Germany). Compression strength of the materials was calculated as an average value of 5–7 determinations.

Vulcanization kinetics of the composite mixes measured directly after preparation and after a week of conditioning is presented in Figs. 2 and 3, respectively. Total torque increase values are gathered in Table 3.

The results obtained demonstrate that addition of CbMix can significantly affect the kinetics of the mix vulcanization or even prevent it, especially after long time of storage. On the whole, the vulcanization kinetics of the mixes occurred very fast, what is important from the point of view of the vulcanization during high-speed extrusion technology used commonly in cable industry. Even CAO mix before storage exhibits a satisfactory vulcanization behavior. Table 3 demonstrates the increase to torque after a week of the composite mixes conditioning. For the majority of the mixes a slight increase in torque value can be observed. The only sample filled with CbMix shows dramatic drop of torque value increase (ΔM) after a time period of conditioning in storage conditions. The negative effect of high amount of CbMix on 2,4-dichlorobenzoyl peroxide cross-linking efficiency of silicone rubber has been already observed previously in the relevant literature [42] and is probably caused by alkaline character of Ca(OH)₂, which is a predominant constituent of the filler. Finally, the peroxide adsorption on the surface of the CbMix particles may contribute to its deactivation.

For the mechanical properties of the composites vulcanized directly after preparation, see Table 4.

Generally almost all samples exhibit tensile strength value over 5 MPa and as such they prove suitable for cable industry, where the value of 5 MPa is often considered the lowest limit for ceramifiable silicone composites utilization. The only sample filled with CbMix (4.3 MPa) does not meet this requirement, which is probably caused by its lower cross-link density in comparison to other composites. The strongest samples were filled with kaolin (5.8 MPa) and calcined kaolin (6.0 MPa). Tensile strength of the composites is closely connected with polar part of the additional filler surface free energy and increases with the decrease of polar part value, (Table 1). This is probably due to the non-polar character of the silicone matrix, which interacts with surface of filler exhibiting polar properties very poorly. Simultaneously, the average size of the functional fillers particles seems not to influence this parameter visibly. This is probably due to their relatively large size facilitating semi- or non-reinforcing properties. In such conditions, the compatibility between the filler surface and silicone rubber plays a much more significant role than the filler capability to form secondary-reinforcing structure inside the elastomer matrix. Elongations at break of the composites are very similar for all samples. However, the composites filled with kaolin (330%) and calcium oxide (330%) exhibit a slightly higher elasticity than others, whereas the composite containing calcium carbonate exhibits the lowest elasticity (290%). Generally, the mechanical properties of the composites depend mostly on the presence of fluxing agent, whose large particles weaken the internal semi-continuous structure of the silicone rubber matrix (Fig. 4). Nevertheless, the presence of an additional mineral filler modifies stress–strain characteristic of the composites noticeably. A much more accurate characteristic of the composites micromorphology along with EDS elemental analysis is available as a supplementary material for this article (Figs. 1S–7S). Except for the reference sample (Ref.) composed only of silicone rubber reinforced with fumed silica and cured with the peroxide, all of the composites exhibit lower values of tensile strength along with elongation at break. This phenomenon was expected due to the non-reinforcing character of the fluxing agent of large particles and semi-reinforcing or non-reinforcing properties of additional, functional fillers. Nevertheless, mechanical properties of the composites emerge as satisfactory from the point of view of their potential application in the cable industry.

Flammability of all the composites is comparable to other flame-retarded silicone-based materials presented in the literature (Table 5) [21]. It is not the low flammability that is the most important feature of the composites, but their ability to form a protective ceramic structure. However, high flame retardancy of the composites is also beneficial from the point of view of ceramification process, which seems to be much more effective when the composites are not exposed to rapid temperature growth. High flame retardancy of composites suppresses growth of fire and temperature, facilitating favorable-mild conditions for ceramification [15].

The addition of CbMix or Al(OH)₃ facilitates the highest increase of the flame retardancy of a ceramifiable silicone composite (Fig. 5; Table 5). Both fillers release considerable amount of water during the heat increase (Fig. 6a) which is accompanied by significant endothermal effect (Fig. 6b). Furthermore, the temperature of water release from these fillers is visibly lower than temperature of CO₂ release from CaCO₃ or water from kaolin. It is highly probable that those three factors combined exert a profound impact on flame retardancy of the composites, especially when KAO composite exhibits one of the worst flame retardant properties from all the composites studied, despite the fact that the kaolin contains over 10% of bonded water. The endothermal effect of water release from kaolin is very low and the temperature range of the release relatively high (above the temperature of thermal decomposition of the silicone rubber matrix). As a result, the addition of kaolin cannot decrease the flammability of the composite effectively. A similar effect is observed for the CACO composite filled with CaCO₃, which releases CO₂ in a too high temperature range to suppress flammability of the composite significantly, despite the considerable endothermal effect accompanying the release (Fig. 6b).

Similarly, in terms of smoke emission intensity, the composite filled with kaolin exhibits the worst properties. Its smoke intensity value places the composite in D2 group with accordance to PN-91/K-02501 standard (≤18,000 lxs). The remaining composites exhibit satisfying properties according to smoke emission density criteria, which place them in D1 group. The lowest smoke emission was observed for TIO sample.

The composites subjected to ceramification were subsequently compared according to their compression strength (Fig. 7). The values of compression force required to crushing of the composite samples are presented in Table 6 as well as the changes of height and diameter of the cylindrically shaped samples. The composites containing calcium-based mineral fillers (CAO, CACO) created the strongest ceramic structure after ceramification. Force required to destroy them was over two times higher than the force required to destroy the third of the strongest samples (TIO). This is most probably the result of formation of different reinforcing polymorphs of CaSiO₃ produced during the thermal treatment of the composites accompanied by highly homogenous micromorphology of these composites. This effect is much thoroughly described in “Micromorphology of ceremified residue”. The weakest ceramic phases were obtained for MIC and AOH samples filled with phlogopite mica (MIC) and aluminum hydroxide (AOH), respectively. All samples exhibit an increase in their height after ceramification, most probably due to the direction of escaping volatiles, whereas the diameter of the samples generally decreases, with an exception of the sample filled with aluminum hydroxide whose diameter is increased by over 2 mm.