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With the continuous progress of textile production technology, more and more new fibers have become raw materials for textiles, which has brought about the problem of identifying fibers used in textiles. The following is an introduction to commonly used fiber identification methods, including microscopy, combustion, reagent colorimetry, staining, dissolution, and so on.
1. Microscopic observation method
Make longitudinal and cross-sectional sections of fibers and observe their longitudinal and transverse morphology under a microscope. Identify fibers based on differences in morphological characteristics, as shown in Table 1.
| Fiber type | Longitudinal morphology | Cross section shape |
|---|---|---|
| Lyocell fiber | Smooth | Regular circular or elliptical shape with skin core layer |
| Modal fiber | There are 1-2 grooves in the longitudinal direction | Irregular, similar to a round waist, relatively smooth, with a leather core |
| Soybean fiber | Irregular grooves and island shaped bumps on the surface | Flat dumbbell shaped and waist circular |
| Bamboo fiber | Surface has grooves | Sawtooth shaped, with a leather core layer |
| Chitin fiber | There are obvious grooves on the surface | The edge is serrated, and there are obvious small gaps in the core layer |
| Viscose fiber | Surface has grooves | Sawtooth shaped, with a leather core layer |
| Cotton fiber | With natural curls | Round waist with a central cavity |
| Ramie fiber | The fiber is relatively thick, with long stripes and bamboo shaped transverse joints | Round waist with a central cavity |
| Flax | Fine fibers with bamboo shaped transverse joints | Polygon with middle cavity |
| Silk fiber | Smooth surface | Irregular Triangle |
| Wool fiber | There are scales on the surface | Circular |
| Copper ammonia fiber | Smooth and glossy surface | Circular or nearly circular |
| Polyester fiber | Smooth surface, rod-shaped | Circular or nearly circular and various irregular cross-sections |
| Acetate fiber | Smooth surface with grooves | Trilobed or irregularly serrated |
| Acrylic fiber | Smooth surface with grooves or stripes | Circular, dumbbell shaped or leaf shaped |
| Nylon fiber | Smooth surface with small black spots | Circular or nearly circular and various irregular cross-sections |
| Vinylon fiber | Flat strip with grooves | Waist or dumbbell shaped |
| Spandex fiber | Smooth surface | Circular or cocoon shaped |
| Chloroprene fiber | Smooth surface, some with bony stripes | Circular or nearly circular |
| Polypropylene fiber | Smooth surface with some scars | Circular or nearly circular |
2, combustion method
During the combustion process, different fibers may have different flame, smoke, odor, residue, etc. Therefore, fiber types can be distinguished based on the characteristics of fiber combustion and after combustion, as shown in Table 2.
| Fiber type | Approaching flames | In flames | Leave the flame | Burning odor | Residue morphology |
|---|---|---|---|---|---|
| Lyocell fiber | Non melting and non shrinkage | Rapid combustion | Continue to burn | Burnt paper flavor | Grey, black, gray |
| Modal fiber | Non melting and non shrinkage | Rapid combustion | Continue to burn | Burnt paper flavor | Grey, black, gray |
| Soybean fiber | Contraction | Burning does not melt, with black smoke | Not easily ignited | Barbecued and flavored | Crispy black gray |
| Bamboo fiber | Non melting and non shrinkage | Rapid combustion | Continue to burn | Burnt paper flavor | Grey, black, gray |
| Chitin fiber | Non melting and non shrinkage | Rapid combustion | Continue to burn | Burnt paper flavor | Grey, black, gray |
| Viscose fiber | Non melting and non shrinkage | Rapid combustion | Continue to burn | Burnt paper flavor | Grey White Grey |
| Cotton fiber | Non melting and non shrinkage | Rapid combustion | Continue to burn | Burnt paper flavor | Grey White Grey |
| Hemp fiber | Non melting and non shrinkage | Rapid combustion | Continue to burn | Burnt paper flavor | Grey White Grey |
| Silk fiber | Contraction | Gradually burning | Not easily ignited | Barbecued and flavored | Crispy black gray |
| Wool fiber | Contraction | Gradually burning | Not easily ignited | Barbecued and flavored | Crispy black gray |
| Copper ammonia fiber | Non melting and non shrinkage | Rapid combustion | Continue to burn | Burnt paper flavor | Grey White Grey |
| Polyester fiber | Shrinkage melting | Melt first and then burn, with solution | Capable of delaying combustion | Aromatic taste | Glass shaped black brown hard ball |
| Acetate fiber | Shrinkage melting | Melt first and then burn, with solution | Capable of delaying combustion | Acetic acid flavor | Irregular black brown hard ball |
| Acrylic fiber | Shrinkage micro melting | Melting combustion with small sparks | Continue to burn | Spicy taste | Black Crispy Hard Block |
| Nylon fiber | Shrinkage melting | Melt first and then burn, with solution | Capable of delaying combustion | Ammonia odor | Glass shaped black brown hard ball |
| Vinylon fiber | Shrinkage melting | Burning | Continue to burn | Special sweet taste | Yellowish brown hard ball |
| Spandex fiber | Shrinkage melting | Molten combustion | Self extinction | Special odor | White adhesive block |
| Chloroprene fiber | Shrinkage melting | Melt combustion, large amount of black smoke | Unable to delay combustion | Hydrogen chloride odor | Dark brown hard lump |
| Polypropylene fiber | Slow contraction | Molten combustion | Continue to burn | Mild asphalt smell | Yellowish brown hard ball |
3. Reagent Colorimetry
Due to the different structures of various fibers, the coloring reactions to iodine and potassium iodide solutions are different. The fibers can be identified by observing the color and swelling of the fibers after the action of reagents. This identification is only applicable to white fibers, and colored fibers need to undergo fading before being tested. Reagent preparation: Dissolve 20 g of iodine in 100 ml of saturated potassium iodide solution, immerse the fibers in the prepared solution for 1 minute, wash with sufficient water, and judge based on their color, as shown in Table 3.
| Fiber type | Lyocell fiber | Modal fiber | Soybean fiber | Bamboo fiber | Chitin fiber |
|---|---|---|---|---|---|
| Iodine solution coloration | Black Blue Blue Blue | Blue Grey | Brown | Blue Grey | Black |
| Fiber type | Viscose fiber | Cotton fiber | Hemp fiber | Silk fiber | Wool fiber |
| Iodine solution coloration | Black Blue Blue Blue | Unstained | Unstained | Light yellow | Light yellow |
| Fiber type | Polyester fiber | Acetate fiber | Acrylic fiber | Nylon fiber | &Nbsp |
| Iodine solution coloration | Unstained | Unstained | Unstained | Black brown | &Nbsp |
4. Staining Method
The use of dyeing method to distinguish fibers is mainly based on the different color reactions of various fibers to dyes. There are two dyeing methods: cold dyeing and boiling dyeing. The formula for dyeing method is shown in Table 4.
Cold dyeing method Boiling dyeing method Dyes Weight (g) Dyes Weight (g)
| Direct Indigo 2B | 2.5 | Acid Fuchsin 6B | 1 |
| Acid Fuchsin 6B | 3 | Base light yellow (concentrated) | 1 |
| Picric acid | 5 | Disperse Blue GF | 0.5 |
| Tannic acid | 5 | Pancreatic bleaching T | 0.5 |
Pour the formula in Table 4 into 50 ml of ethanol, stir and dissolve, and then dilute with distilled water to 500 ml for later use. The cold dyeing method directly puts the fibers into the solution for dyeing, then rinses the fibers with cold water, squeezes out water, and observes the color for identification; The boiling dyeing method involves adding fibers to a solution for dyeing, boiling for 3 minutes, rinsing 3 times, and then rinsing them in a 0.1% pancreatic bleaching T solution. The fibers are then squeezed out of water and the color is observed for identification. The dyeing reactions of various fibers are shown in Table 5.
| Fiber type | Cotton fiber | Viscose fiber | Vinylon | Acrylic fiber | Nylon |
|---|---|---|---|---|---|
| Cold dyeing method | Purple | Red Purple | Light yellow green | Not colored | Light yellow |
| Boiling dyeing method | Earthy yellow | Light yellow | Dark Olive Green | Light Sky Blue | Dark grass green |
5. Dissolution Method
Qualitative identification of plant fibers, animal fibers, mineral fibers, and chemical fibers can be achieved by using different chemical reagents to investigate the dissolution characteristics of different fibers at different temperatures. Can be used for qualitative identification of fibers. There are many chemical reagents that can be used for qualitative identification of fibers, such as sulfuric acid, hydrochloric acid, formic acid, nitric acid, sodium hydroxide, zinc oxide, N-dimethylformamide, sodium hypochlorite, cyclohexanone, copper ammonia solution, glacial acetic acid, acetone, dimethyl sulfoxide, etc. During the inspection, attention should be paid to the influence of reagent concentration and temperature on the test results. The test temperature is generally divided into room temperature (24-30 ℃) and boiling. The solubility test method can accurately identify various types of textile fibers.
6. Coloration reaction method with chlorine and nitrogen
The chlorine and nitrogen containing color reaction method can be used for rough classification of chemical fibers for further qualitative identification. Its experimental principle is that various chlorine and nitrogen containing fibers are detected by flame method or acid-base method, and will exhibit specific color reactions. Chlorine test: After touching the fibers with hot copper wire, move it to the oxidation flame of the flame and observe if the flame is green. If there is chlorine, a green flame will occur. Nitrogen test: Place a small amount of chopped fibers in a test tube, cover with an appropriate amount of sodium carbonate, heat to produce gas, and place a red litmus test paper at the mouth of the test tube to turn blue, indicating the presence of nitrogen. Among the existing textile fibers, chlorine containing fibers are mainly polyvinyl chloride and polyvinylidene chloride fibers, while nitrogen containing fibers include silk, wool fibers, polyacrylonitrile fibers, polyamide fibers, and polyurethane fibers.
7. Melting Point Method
Under the action of high temperature, thermoplastic fibers undergo a change in the bonding structure between macromolecules, resulting in a transition from solid to liquid state. Using a polarizing microscope or melting point microscope with a heating device, the fiber melting temperature (base melting point) can be measured by visual or photoelectric detection from changes in the appearance and morphology of the fiber. Different types of thermoplastic fibers have different melting points, which can be used to identify the types of fibers. The melting point method is generally not used solely for qualitative identification of fibers, but rather for verification and determination of the melting point of thermoplastic fibers. This is because some fibers have relatively close melting points, while others do not have obvious melting points.
8. Infrared Spectral Identification Method
The experimental principle for qualitative identification of various textile fibers using infrared spectroscopy is that when a beam of infrared light is irradiated on the tested sample, a portion of the light energy absorbed by the substance molecules is converted into the vibration and rotation energy of the molecules. By using an instrument to plot the absorption value with the corresponding wave number, the infrared absorption spectrum of the sample can be obtained. Each characteristic absorption band in the spectrum contains information about the functional groups in the sample molecules. Different substances have different infrared spectra. By comparing the standard infrared spectra of unknown fibers with known fibers, the category of fibers can be distinguished.
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