Patent Application
20090092645
1. Field of the Invention
The invention is related to an innovative radiation method for fabrication of nano-metal compound antibacterial fabric textile. Especially it refers to the process that uses high-energy γ-ray treatment to the surface of Nylon or PET fiber to start the reaction of the silver compound and form the antibacterial nano-composite.
2. Description of the Prior Art
Presently the antibacterial textile products basically use silver nano-particles as antibacterial additive. Due to its excellent thermal stability, it can be added into fiber mother solution. Then after spinning process, antibacterial fiber can be produced. However since the diameter of nano-particles is very small and their surface activity is large, they tend to form aggregates under the high-temperature influence in the process. To stabilize and disperse nano-particles, it requires the use of dispersants. In this way, not only the cost will increase but also the process will become difficult. It is desired to develop a new technology to simplify the manufacturing process that will firmly fasten inorganic antibacterial particles onto textile fibers in the back stage of the process.
Since 1960, radiation technique has been used to effectively make two different polymers into copolymers through grafting or crosslinking mechanism [Hughes, 1973]. This is because when the material surface is exposed to radiation the material becomes in an excited state and produces free radicals and peroxides to initiate grafting and crosslinking reactions. Radiation grafting technique can simply combine two different polymers through radiation. The process is simple and has a great potential to textile industry. Presently, there are examples of using Co-60 radiation to graft acrylic acid, N-isopropylacrylamide or chitosan onto nonwovens [Hao-Tsi Lin, 2003] to improve hydrophilicity, function and bactericidal ability. But the reaction is a little complicated because it requires Co-60 radiation to form membranes of acrylic acid or N-isopropylacrylamide on fibers first, and then uses UV radiation to graft chitosan. The invention is to further simplify radiation technique for antibacterial fabric manufacturing process. The fabric material is commonly used Nylon or PET.
Based on bactericidal principles, the antibacterial materials can be divided into two categories, organic bactericidal powders and inorganic bactericidal powders. In the last century, people developed a variety of organic bactericides to fast and effectively eliminate bacteria [Maxwell and Critchlow, 1997; Subbalakshmi and Sitaram, 1998]. Although organic bactericides have strong bactericidal effect, their biggest shortcoming is bacteria tend to generate resistance to them. Besides, organic bactericides have shortcomings in poor thermal stability and poor chemical stability et al. They are not suitable for radiation grafting technique. This is also why inorganic bactericides receive more attention. Further, inorganic bactericides can be divided into photocatalyst type, like nano titanium dioxide, nano zinc oxide et al., and traditional silver bactericide type. The photocatalyst type of bactericides has a passive bactericidal mechanism, requiring sunlight or UV ray radiation to produce bactericidal effect. The biggest shortcoming of photocatalyst type is that it decomposes fiber while it is decomposing bacteria. On the other side, silver bactericide type can actively interact with enzymes in bacteria or destroy cell walls to achieve bactericidal effect. Thus, the invention selects silver bactericides as the starting reactants for antibacterial textiles.
Since textile products require lightweight, thinness and softness in use, the inorganic bactericidal powders need very small diameter. With the development of nano-technology, presently there are various techniques to reduce the particle size to nano scale. Besides, nano-particles have apparently different characteristics from bulk materials. Adding nano-particles could enhance intrinsic material properties and develop different properties. The invention uses radiation technique to combine silver bactericides and polymer fibers to product lightweight antibacterial textiles.
References:
1. Hughes G., Radiation Chemistry, Oxford University Press, London, UK, (1973).
2. Hayashi S., K. Fujiki, N. Tsubokawa, Grafting of hyperbranched polymers onto ultrafine silica; postgraft polymerization of vinyl monomers initiated by pendant initiating groups of polymer chains grafted onto the surface, Reactive & Functional Polymers, 46, (2000) 193-201.
3. Hao-Tsi Lin, Use of Co-60 Radiation and UV Radiation to Modify the Hydrophilicity and Bactericidal Effect for Polypropylene Nonwovens with Acrylic Acid, N-isopropylacrylamide or Chitosan, Chang Gung University Ph.D. thesis (2003).
4. Maxwell A, Critchlow S. E. : Mode of Action, In Quinolone Antibacterials, Edited by Kuhlmann J., Dalhoff A., Zeiler H. J., Springer Verlag (1997), P. 119.
5. Subbalakshmi C. N. Sitaram: Mechanism of antimicrobaial action of indelicidin, FEMS Microbiol Letts, (1998), P. 91.
The main objective for the invention is to use radiation technique to graft inorganic silver bactericides onto Nylon or PET fibers to produce antibacterial performance textiles.
Basically, nano-fabrication of antibacterial textiles is to use materials like silver nano-particles as bactericidal additive. Due to its excellent thermal stability, it can be added to fiber mother solution, which followed by spinning leads to producing antibacterial fibers. Since the diameter of nano-particles is very small and their surface activity is large, they tend to form aggregates under the high-temperature influence in the process and they are difficult to combine with fibers. It is necessary to develop a new technology to simplify the manufacturing process that will firmly fasten inorganic bactericidal nano-powders onto fibers in the back stage of the process.
The purpose of the invention is to use silver nano-compound as performance additive, which uses radiation modification to reduce and deposit silver particles onto PET or Nylon fiber surface. Such products, after SEM (scanning electronic microscope), ICP (inductively coupled plasma), XPS (X-ray photoelectron spectroscopy) and bactericidal test et al., have proved to have excellent antibacterial performance.
The radiation technique for the invention is to use Co-60 γ-ray (or E-beam) radiation on fiber materials. It includes mutual irradiation process and pre-irradiation process, which has main steps as follows:
1. Mutual Irradiation Process
(a) Cut Nylon-6 or PET fabric into ≧20 cm×20 cm base material;
(b) Immerse Nylon-6 or PET base material in silver/silicon dioxide (Ag/SiO2) or silver nitrate solution for over two hours;
(c) Take out the fabric material and press it over 2.0 kg/cm2 under rollers to squeeze out excessive silver nitrate solution;
(d) Put Nylon-6 or PET fabric material into a plastic bag, such as PE ziplock bag, for radiation treatment.
2. Pre-Irradiation Process:
(a) Cut Nylon-6 or PET fabric into ≧20 cm×20 cm base material;
(b) Put Nylon-6 or PET fabric material into a plastic bag, such as PE ziplock bag, for radiation treatment;
(c) Immerse Nylon-6 or PET fabric material in silver/silicon dioxide (Ag/SiO2) or silver nitrate solution for different immersion times. Take out the material to pressing treatment. Place the material in oven for fast drying.
Take two different fabric materials in the same size (≧20×20 cm2). Immerse the Nylon or PET fabric material in a suspension solution of over 2.0 wt % Ag/SiO2 bactericidal powers for over two hours. Use press to remove excessive liquid. Then we use radiation less than 100 kGy to combine bactericidal powders and fabric material. Clean the fabric material to obtain the antibacterial product.
Cleaning is usually thought to remove the bactericidal powders that are on fiber surface through van der Waals forces. Silver containing fibers after agitation, with fiber surface subject to collisions and shaking, for a long time shall have grafting between surface remaining bactericidal nano-powders and fibers.
To determine the silver content after radiation exposure, concentrate nitric acid was used to dissolve the silver in the nano-powders on the fabric (because silver reacts with nitric acid to form silver nitrate). Then ICP is used to quantitatively determine the silver content of antibacterial fabric. Table 1 is the powder content and silver content for Nylon or PET fabric after Co-60 irradiation of less than 100 kGy. From Table 1 it is clearly seen than the silver content is as high as 1 wt % before cleaning. But after cleaning, the silver content decreases a lot, which indicates only a small amount of bactericidal nano-powders remain on the fabric surface after cleaning. From Table 1, it is also PET fiber has much less silver content than Nylon fiber. By calculation, it is found SiO2 from Ag/SiO2 and Ag/SiO2P SiO2 remain 15 wt % and 16 wt % respectively on Nylon surface after cleaning. The amount of powders on PET surface is low. It is 5 wt % and 4 wt % from Ag/SiO2 and Ag/SiO2P respectively. Because the two bactericidal powders have relatively low silver content, Nylon or PET fabric has low silver content.
The irradiation method uses radiation to directly reduce silver particles on fiber surface. First, cut Nylon or PET fabric material (≧20×20 cm ) to immerse in silver nitrate solution for over two hours. Squeeze out excessive liquid by pressing. Then proceed with radiation in less than 80 kGy.
a) the SEM pictures for PET immersed in silver nitrate and exposed to radiation. From the SEM pictures, it is found before cleaning PET fiber surface has silver distribution in tree-branch or granular deposits. After cleaning the tree-branch deposits are removed, but many tiny silver particles remain on fiber surface, as shown in
Table 2 shows the ICP measured amount of grafted silver on fiber surface before and after cleaning. For PET and Nylon fabrics immersed in over 0.25M silver nitrate solutions and pressed later, after cleaning the ICP measurement indicates silver content of 11.57 wt % and 15.33 wt % respectively. After water cleaning the silver content is greatly reduced to 1.08 wt % and 2.15 wt % respectively. This should be the silver content for those particles bonded to fiber surface. Besides, PET has much lower silver content than Nylon because PET fabric is hydrophobic and contains less water after pressing.
Besides the above post-irradiation and direct-irradiation methods, the process method also studies the variation of silver content for Nylon or PET fabric under pre-irradiation. The process for pre-irradiation is described as follows: irradiate Nylon or PET fabric with y-ray less than 60 kGy and immerse it in silver nitrate solution for over 20 minutes; proceed with pressing, drying and cleaning to produce nano antibacterial textile.
Table 3 shows the amount of silver content for fabric after pre-irradiation. From the table, it is known that the pre-irradiated fabric after cleaning has low silver content, less than 0.1 wt %. There are two reasons: first, the free radicals or peroxides produced on Nylon or PET surface exist for a very short of time and fail to reduce the silver ions in silver nitrate solution; second, the reduced silver particles need hydrated electrons, but the pre-irradiation fails to provide sufficient hydrated electrons to effectively reduce the silver ions in the solution.
From the above results and bactericidal test, it is known that except the pre-irradiation effect is not clear, the remaining two methods have strong bactericidal effects. Especially the Nylon or PET fabric with silver from direct radiation and reduction process has significant bactericidal effect, with bactericidal power up to 99.0% (with respect to Staphylococcus aureus). The silver containing in PET bactericidal performance is better than that of Nylon.
