Basalt fibers as functional additives in coating of textiles

As basalt fibers, UCF fibers (uncoated chopped fibers) are used. These basalt fibers are supplied by the company Deutsche Basalt Faser GmbH (Sangerhausen, Germany). According to supplier information, the diameter of all used basalt fiber types is 13 µm. Altogether, three different types of basalt fibers are investigated, which have different fiber lengths of 0.16, 1.6 or 4 mm, according to supplier information. A photographic image of the used basalt fibers with a length of 4 mm is shown in Fig. 1. The typical brown coloration of basalt fibers is obvious. SEM images of the used basalt fibers of all three lengths are presented in Fig. 2 in two different magnifications. By view of these SEM images, it is clear that the basalt fibers containing 1.6 mm length are roughly ten times longer compared to fibers with length of 0.16 mm. However, for all types of fibers, fiber pieces with significantly shorter length or broken pieces are observed. These smaller fibers or broken pieces are probably the result of mechanical influences appearing after fiber production. As a result of the mechanical forces, e.g., occurring during storage, package or transportation, some fibers break into smaller pieces. Beside the length of the basalt fibers, the fiber diameter also varies in a certain range around the value of 13 µm, which is given by the supplier. According to supplier information, these basalt fibers are dedicated for the use as additive in polymers to improve thermal and mechanical properties of modified polymers. For current investigations, two different types of binders are used for coating preparation on the textile fabric. First, the acrylate-based binder Printperfekt 226FF is used. This binder is supplied by the CHT R.Beitlich GmbH (Tübingen, Germany). Second, the polyurethane binder Printperfekt Base FF is used, which is supplied by the same company. For some preparations, the application with the binder Printperfekt 226FF is modified with the silicate compound Aerosil COK 84 (Evonik, Germany). As the textile substrate, a white plain weave cotton fabric is used.

For coating preparation, at first a basalt fiber-containing printing paste is prepared. For this, the basalt fibers are stirred into the used binders in different concentrations in the range from 2.5 to 50 wt%. If the recipe is modified by adding the silicate compound Aerosil COK 84, the Aerosil is added at first to the basalt fibers in a concentration of 2 wt%. The application of the printing paste onto the textile substrate is done by using a Mathis Labdryer type LTE which is equipped with a coating device (supplied by the company Werner Mathis AG, Switzerland). The coating application is done in two layers. After application of each layer, the samples are dried at 80°C for a duration of 1 min.

The topography of coated samples is investigated using a scanning electron microscope (SEM) Tabletop TM3000 supplied by Hitachi (Japan). SEM images of sample cross sections are recorded by an SEM TM4000plus Tabletop Microscope (Hitachi, Japan). Optical spectra are recorded from the samples in arrangement of diffusive reflection and diffusive transmission. For these optical measurements, a photo spectrometer UV-2600 from Shimadzu (Japan) is used. This spectrometer is equipped with an integrated sphere enabling the measurements in diffusive arrangement. The optical measurements are done in a spectral range from 220 to 1400 nm. For documentation of color properties of prepared samples, the CIE L*a*b* indices are measured. These measurements are done with a device DATA Color 400 (Rotkreuz, Switzerland).

The microscopic measurements of the prepared coatings are done by scanning electron microscopy (SEM) to investigate the surface topography of realized coated fabrics. Beside the surface topography, the used SEM device also enables the depiction of a material contrast, so the deposited basalt fibers are shown in brighter contrast compared to the polymeric binder and the textile substrate. The material contrast is related to the inorganic content of the basalt fibers containing mainly silica and alumina. Silicon Si and aluminum Al are chemical elements of higher weight, which leads to a different material contrast compared to the polymer binders and the cotton fabric containing mainly the chemical elements carbon C, oxygen O and hydrogen H.31

The SEM images of cotton fabrics carrying the acrylate coating with the basalt fibers are shown in Fig. 3. In Fig. 3, samples with an increasing content of basalt fibers from 2.5 up to 50% in the coating recipe are compared. These samples are prepared by using fibers of shortest length 0.16 mm. With these short fibers, stable coating recipes can be prepared even if the fiber concentration is set to high values of 50%. If the basalt fiber concentration is 30% or higher, the complete fabric is covered by the fibers. In the case of the lowest investigated concentrations of 2.5% and 5%, the basalt fibers are nearly randomly oriented on the cotton substrate. With use of higher fiber concentration in the coating recipe, a trend to a parallel orientation of many basalt fibers can be observed (Fig. 3).

The occurring parallel orientation could be the result of an arrangement occurring during application of the coating recipe and its drying on the textile substrate. It could be assumed that the deposited basalt fibers have a certain influence on the orientation of the next deposited basalt fibers. If the basalt fibers are applied in low concentration, the distance between the single deposited basalt fibers is large, so contact between the deposited basalt fibers occurs in smaller amounts and the fibers are more randomly distributed. By applying a medium or high concentration of basalt fibers, the distance between the fiber in the coating is decreased and a parallel orientation of some basalt fibers occurs.

A cross section of a coated fabric is presented in Fig. 4. This SEM image shows a cross section of a cotton fabric with a basalt fiber-containing acrylate coating. The basalt fibers are 0.16 mm in length and are added in a concentration of 10% to the coating recipe. All three types of materials are clearly visible in the microscopic images—the basalt fibers, the fibers of the cotton fabric and the binder in between both fiber types. The thickness of the coated cotton substrate is around 200 μm. The coating on top of this substrate is around 25 μm thick. This top part of the coating contains the unbroken basalt fibers. The acrylic binder and smaller pieces of broken basalt fibers can penetrate deeper into the free areas of the cotton fabric, so for these areas altogether, thicknesses of up to 100 μm can be reached (Fig. 4).

Acrylate coating recipes prepared with basalt fibers containing a longer fiber length of 1.6 mm or 4 mm are realized and applied with a basalt fiber concentration of 2.5%. With higher concentrations, the stability of the coating recipe is limited due to occurring segregation of the coating recipe. The related SEM images of coated samples with longer basalt fibers are presented in Fig. 5. It can be determined that many of the longer fibers are broken into smaller pieces, likely due to mechanical influences during recipe preparation and application of the coating onto the textile surface. Also, the hand feeling of cotton substrates changed drastically after coating with longer basalt fibers. These coated cotton fabrics exhibit a hard and scratchy hand feeling making them unsuitable for any clothing application.

Additionally, to the simple acrylate binder, coating recipes based on a polyurethane binder and an acrylate binder modified with the silicate Aerosil are also evaluated. The related SEM images are depicted in Figs. 6 and 7. Figure 6 shows SEM images in low magnification of basalt fiber with 0.16 mm length added in a concentration of 20% to different binder systems. It is clearly seen that with different binder systems, a parallel orientation of some basalt fibers occurs. For this, it can be stated that the above-mentioned orientation of some basalt fibers during the coating process is independent from the type of used binder.

In Fig. 7, SEM images in higher magnification are presented. Also, in these higher magnified images, the parallel orientation of some basalt fibers is observed. In all images, smaller pieces of basalt material are observed. These smaller basalt pieces are obviously residues from broken basalt fibers, which are destructed during the recipe preparation and the coating application. For the acrylate recipe containing the silicate additive Aerosil, the Aerosil particles can also be detected in the related SEM image (Fig. 7). The Aerosil particles are regularly distributed in the binder layer.

The optical properties of realized coated samples are investigated by using optical spectroscopy with wavelengths of light in the range of 220–1400 nm. The aim of this investigation is the evaluation of the samples related to their interaction with different types of light. First, the view to the investigated region of UV light from 220 to 400 nm is done to evaluate if the applied coatings can act as a UV-protective material. Second, the investigation related to the area of visible light from 400 nm to 750 nm is done to gain information according to the coloration of the prepared coatings. These coloration measurements are accomplished by determination of the CIE L*a*b* indices. Third, the view to the investigated region of IR light from 750 to 1400 nm is done to determine if the applied coatings can influence the interaction to IR light and can lead to an application as a heat protective material.

The performed spectroscopic investigations are done in two different arrangements—reflection or transmission—due to different purposes. The reflection measurements give mainly information on the color change after coating application, while the transmission is related to radiation protective properties. For reference measurements, an uncoated cotton fabric is used.

Determined reflection spectra of the coated fabrics are presented in Figs. 8 and 10. Figure 8 summarizes the reflection spectra of all samples which are acrylate based and contain basalt fibers with a length of 0.16 mm. Here, the reflection spectra are compared due to the different content of basalt fiber concentration from 2.5% up to 50%. It is obvious that the applied coatings decrease the reflection over the complete investigated spectral range from 220 to 1400 nm. This decrease in reflection is clearly correlated to the amount of added basalt fibers to the coatings. Because of the brown coloration of the basalt fibers themselves, the decrease in reflection in the visible range of light can be expected. Also, the higher reflection values for red light compared to lower reflection values for light in the range of 400–500 nm is related to the brown coloration of the basalt fibers. Applications of coatings with basalt fiber concentration of 30% or more lead to dark brown colored samples. Beside this influence on visible light, the reflection of UV-light is even more strongly decreased (Fig. 8). Samples with high basalt fiber content of 30% or more exhibit reflection values smaller than 5% over nearly the complete UV-range. Compared to the decrease in reflection for UV-light and visible light, the reflection of IR-light is less decreased by the applied coatings. For this, a stronger infrared reflection compared to the other types of investigated light can be stated.

Figure 9 shows a data evaluation of the reflection spectra presented in Fig. 8. In Fig. 9, the reflection values at four different wavelengths of the recorded spectra are shown as a function of the basalt fiber concentration in the applied coating. As four wavelengths, the values at 300 and 380 nm (both representative for UV-light), 500 nm for visible light and 900 nm for IR-light are selected. It is clearly seen that there is a strong decrease in reflection as a function of the basalt fiber concentration up to a concentration of 30%. A further increase in the basalt concentration to values up to 50% does not lead to a further strong decrease in reflection values. For this, it can be stated, that for basalt concentrations in the range of 2.5–30%, an increase in basalt fiber component leads to a progressed covering of the white cotton fabric by the brown colored basalt fibers. Here an increase in basalt concentration has a direct influence in the reflection properties. For concentrations of 30% or higher, the cotton fabric is nearly completely covered by the basalt fibers, so a further addition of more basalt component does not lead to a further change in coloration of the sample.

In Fig. 10, the reflection spectra of samples with the same concentration of basalt fibers (20%) but with different binder recipes are compared. It is clearly seen that the type of used binder has nearly no influence on the optical properties of the realized coated samples. It can be stated that the optical active component in these coatings is the basalt fiber.

Determined transmission spectra of the coated fabrics are presented in Figs. 11 and 13. Figure 11 summarizes the transmission spectra of all samples which are acrylate based and contain basalt fibers with a length of 0.16 mm. Here, the transmission spectra are compared due to the different basalt fiber concentrations from 2.5 up to 50%. The transmission of UV light in the range from 220 to 300 nm is drastically reduced even if only low amounts of basalt fibers are added to the coating. With high basalt fiber concentration of 30% or more, the transmission in this spectral range is near zero. For this, it can be assumed that the basalt fibers strongly absorb UV light with wavelength of 300 nm or shorter. Nevertheless, a different result is gained for the UV area between 300 and 400 nm. This observed transmission behavior is in good accordance to the transmission reported for nonwoven fabrics made from basalt fibers.24 Of course, in this area, the transmission of UV light is also decreased by the basalt fiber-containing coatings but, especially in the spectral range of 370–400 nm, a complete decrease to very low transmission is only reached for highest basalt fiber concentration. It should be kept in mind that this spectral region is especially important for UV protection against sun light because the UV content of sun light occurs especially in this region.32 For this, an excellent UV protection is only possible by application of coatings containing the high basalt fiber concentration.

UV-protective properties can be reached by application of UV-light absorbing components, which are called UV-absorbers. Often, two kinds of UV-absorbers are distinguished, which are inorganic UV-absorbers like TiO₂ and organic UV-absorbers.33,34 The UV-protective properties of inorganic UV-absorbers such as TiO₂ or ZnO are determined by the band-gap of this absorber, and below the wavelength related to the energy of the band-gap, the UV-light is completely absorbed.33,35 Organic UV-absorbers are comparable with organic dye stuffs and absorb UV-light of a certain spectral range.33 Beside TiO₂ as an inorganic UV-absorber, the use of zinc oxide is also reported for the application of UV-protective properties on textiles.35‐37

The basalt fiber-containing coating can be compared to applications using inorganic UV-absorbers. The basalt fibers are also an inorganic material absorbing UV-light below a certain wavelength and give a good UV-protection for this spectral range. This UV-absorbing property of basalt fibers is also related to a certain content of TiO₂ in this type of fiber. Due to the additional content of iron oxide in the basalt fibers, UV-light with wavelengths higher than the bad-gap of TiO₂ and also visible light are absorbed by the basalt fiber-containing coatings. For this, especially in the spectral range between 370 and 400 nm, the UV-protective properties of basalt-containing coatings are better compared to systems using only zinc oxide or titanium oxide. However, by using organic UV-absorbers, better UV-protective properties in the spectral range from 370 to 400 nm are reached on polymer foils and textiles.33,38

The transmission for the visible and infrared light is also decreased as a function of basalt fiber concentration in the coating. However, in contrast to the reflection, the transmission for visible and IR-light decreased with a nearly linear behavior as a function of basalt fiber concentration (Fig. 12). The reflection is related to the coverage of the textile substrate. In contrast, the transmission is not only depending on the coverage. Also, the content of basalt fiber in deeper areas of the coating leads to an absorption of light during its transfer through the coating. By this, a decrease in transmission occurs. With basalt fiber coatings, it is possible to create textiles with low transmission values for visible and IR light of smaller than 5%, while the reflection, especially for IR-light, is still higher with values of > 15% (Figs. 9 and 12).

In Fig. 13, the transmission spectra of samples with the same concentration of basalt fibers (20%) but with different binder recipes are compared. It is clearly seen that the type of used binder has nearly no influence on the optical transmission of the realized coated samples. It can be stated that the component determining the optical transmission of these coatings is the basalt fiber.

In contrast to UV-protective materials, IR-protective materials are based not only on the absorption of infrared-radiation. Also, the reflection of infrared-radiation is an important mechanism here, which is especially used in metal coated textiles by the use of high reflective pigments. A good example in this field is the coating of cotton fabrics with thin metallic silver films. As a result, the nearly complete shielding of infrared radiation can be reached.39 Here the applied silver films increase the reflectivity for IR-light and thus, the transmission for this IR-light is decreased.39 A similar effect is reported for copper films on polyester and cotton.40 By application of ZnO nanoparticles, the IR-reflectance of black cotton fabrics can be increased.35 However, with other metal coatings, such as titanium, this effect cannot be reached.40

In contrast to these IR-reflecting materials, the developed basalt fiber coatings lead to a decrease in IR-reflection and simultaneously to a drastic reduction in the transmission for IR-light. The reason for this decrease is likely due to a strong absorption of IR-light by the basalt fibers. Because of the decreased transmission, the basalt fiber coated textiles can be used as protective materials against IR-light. The lower reflection of IR-light has the advantage that other materials or persons are not exposed by the reflected IR-light.

Altogether it can be stated that the developed basalt fiber coatings on textiles can lead to applications for simultaneous protection against UV-light and IR-light by only one coating application. Of course, the UV-protection in the spectral range of 370 to 400 nm could be further enhanced by addition of an organic UV-absorber especially dedicated for this spectral area of UV-light. However, the development of a combined application of basalt fibers and organic UV-absorbers in the same coating goes beyond the scope of the actual study.

Beside the changes of optical properties for UV- and IR-light, the optical properties for visible light and, by this, the coloration of samples is changed after the coating application. The reflection spectra exhibit a significant decrease in reflected light as a function of basalt fiber concentration added to the coating (Figs. 8 and 10). By this, a darker coloration after coating is determined. In addition to the optical spectroscopy, the sample coloration is determined by using CIE L*a*b* indices (Table 1). In comparison to the uncoated cotton reference, a clear change in CIE indices after coating application is determined. This change in CIE indices is increased as a function of basalt fiber concentration in the applied coating. The index for brightness L* is decreased from 85.33 as the value of the cotton reference down to 34.07 for the textile with the highest basalt fiber concentration. This result from CIE measurement is in good agreement with the reflection spectra determined by optical spectroscopy for the range of visible light (Fig. 8). Also, by the reflection measurements, a significant decrease in reflection is determined if basalt fibers are added in higher concentrations. In fact, basalt fibers exhibit a brown coloration, so a coating containing basalt fibers changes the color of the coated fabric to dark brown. The change of the index a* from negative to positive values after basalt fiber applications indicates a shift to a redder coloration of the samples after coating. The increase in the index b* after basalt fiber application indicates a change to a yellower coloration after coating. In fact, this is the red-brown coloration of basalt fiber which is transferred to the coated textile.