CN112267292A - Antibacterial and antistatic fabric and preparation method thereof - Google Patents

Abstract

The application relates to the field of fabrics, and particularly discloses an antibacterial and antistatic fabric and a preparation method thereof. A preparation method of an antibacterial and antistatic fabric comprises the following steps: s1, feeding the fabric into the antibacterial antistatic dispersion liquid, ultrasonically soaking for 15-30S, and taking out to obtain a pretreated fabric; s2, drying the pretreated fabric until the water content of the pretreated fabric is lower than 85% to obtain the dried pretreated fabric; s3, drying the pressed and dried pretreated fabric at the temperature of 45-65 ℃ to obtain the antibacterial and antistatic fabric; the antibacterial antistatic dispersion liquid is prepared from the following raw materials: nano titanium dioxide, an ultraviolet absorber, nano graphene oxide, diatomite, silver nitrate, water and a dispersing agent. The antibacterial and antistatic fabric prepared by the method can be used for preparing towels, clothes and the like, and has the advantages of good antistatic performance and good antibacterial performance.

Description

Antibacterial and antistatic fabric and preparation method thereof

Technical Field

The application relates to the field of fabrics, in particular to an antibacterial and antistatic fabric and a preparation method thereof.

Background

Static electricity, which is a static or non-flowing charge, is formed when the charge accumulates on an object or surface. For example, when the chemical fiber clothes rub the human body in winter and the weather is dry, the human body can feel the electric shock needle-prick feeling, which is a bad place of static electricity.

Moreover, the persistent static electricity can cause the pH value of the blood of a human body to be increased, the excretion amount of calcium in urine to be increased, and the blood calcium to be reduced, thereby having adverse effects on the heart, the brain and the skin of the human body.

In recent years, many people have studied antistatic fabrics, and finally, the reason that the antistatic effect of the fabrics can be improved by enhancing the moisture absorption performance of the fabrics is that the static leakage amount of the fabrics is improved after the fabrics absorb moisture in the environment.

However, after the moisture absorption performance of the fabric is enhanced, the fabric is in a relatively humid environment in an environment with high humidity, and the environment is suitable for bacteria growth, so that the fabric is easy to breed bacteria. However, the fabric after breeding bacteria is easy to generate some peculiar smell, and bacterial plaque is easy to form on the fabric when serious, thereby influencing the use of people.

Disclosure of Invention

In order to improve the antistatic performance of the fabric and improve the antibacterial performance of the fabric, the application provides the antibacterial and antistatic fabric and the preparation method thereof.

In a first aspect, the application provides a preparation method of an antibacterial and antistatic fabric, which adopts the following technical scheme:

a preparation method of an antibacterial and antistatic fabric comprises the following steps:

s1, feeding the fabric into the antibacterial antistatic dispersion liquid, ultrasonically soaking for 15-30S, and taking out to obtain a pretreated fabric;

s2, drying the pretreated fabric until the water content of the pretreated fabric is lower than 85% to obtain the dried pretreated fabric;

s3, drying the pressed and dried pretreated fabric at the temperature of 45-65 ℃ to obtain the antibacterial and antistatic fabric;

the antibacterial antistatic dispersion liquid is prepared from the following raw materials in parts by weight:

nano titanium dioxide: 3-6 parts of

Ultraviolet light absorber: 0.3 to 0.6 portion

Nano graphene oxide: 0.6 to 1 portion

Diatomite: 2-5 parts of

Silver nitrate: 0.05 to 0.1 portion

Water: 50 portions of

Dispersing agent: 0.5-1 part.

By adopting the technical scheme, the diatomite has good moisture absorption performance, and can quickly leak out static electricity generated by the fabric, and the addition of silver nitrate can further improve the conductive capability and the antistatic property of the fabric; in addition, the nanometer titanium dioxide and the ultraviolet absorber have a synergistic effect, so that the antibacterial performance of the fabric can be enhanced, the fabric has the advantages of good antistatic performance and good antibacterial performance, the harm of static electricity to a human body is reduced, and the problem that the fabric is easy to grow bacteria to cause odor or bacterial spots is solved.

Preferably, the preparation method of the antibacterial antistatic dispersion liquid is as follows:

preparing an activated antibacterial agent:

ball-milling the mixture of the nano titanium dioxide, the ultraviolet absorber and the nano graphene oxide at the ball-milling speed of 150 and 250rad/min for 1-3h to obtain the antibacterial agent;

irradiating the antibacterial agent under ultraviolet light for 30-60min to obtain activated antibacterial agent;

preparing an antistatic agent:

adding silver nitrate into water, and stirring and dissolving to obtain a silver nitrate solution;

adding diatomite into a silver nitrate solution, and uniformly stirring to obtain an antistatic agent;

preparing an antibacterial antistatic dispersion liquid:

adding an activated antibacterial agent and a dispersing agent into an antistatic agent, and dispersing by ultrasonic vibration to obtain an antibacterial antistatic dispersion liquid.

By adopting the technical scheme, after the activated antibacterial agent and the antistatic agent are uniformly mixed to obtain the antibacterial and antistatic dispersion liquid, the antibacterial and antistatic dispersion liquid is adopted to treat the fabric, so that the fabric can be treated by only one step to obtain the fabric with both the antistatic property and the antibacterial property, and the fabric has the advantages of simple operation process and low equipment requirement.

Preferably, the ultraviolet light absorber is one or a combination of more of salicylate ultraviolet light absorber, benzophenone ultraviolet light absorber and benzotriazole ultraviolet light absorber.

By adopting the technical scheme, the ultraviolet light absorbent can adopt any one or a combination of a plurality of salicylic acid esters, benzophenones and benzotriazoles, can be selected according to actual needs in the actual production process, and is favorable for controlling the cost.

Preferably, the antibacterial antistatic dispersion liquid further comprises the following raw materials in parts by weight:

metal salts of stearic acid: 0.8 to 1.2 portions of

Phosphite ester: 1-1.5 parts.

By adopting the technical scheme, the metal stearate and the phosphite ester are added into the antibacterial antistatic dispersion liquid, wherein the metal stearate and the phosphite ester have a synergistic effect on the improvement of the stability of the ultraviolet light absorbent, so that the antibacterial performance of the fabric can be further enhanced.

Preferably, the preparation method of the antibacterial antistatic dispersion liquid is as follows:

preparing an activated antibacterial agent:

ball-milling a mixture of nano titanium dioxide, an ultraviolet absorber, a metal stearate, phosphite ester and nano graphene oxide at the ball-milling speed of 150-250rad/min for 1-3h to obtain an antibacterial agent;

irradiating the antibacterial agent under ultraviolet light for 30-60min to obtain activated antibacterial agent;

preparing an antistatic agent:

adding silver nitrate into water, and stirring and dissolving to obtain a silver nitrate solution;

adding diatomite into a silver nitrate solution, and uniformly stirring to obtain an antistatic agent;

preparing an antibacterial antistatic dispersion liquid:

adding an activated antibacterial agent and a dispersing agent into an antistatic agent, and dispersing by ultrasonic vibration to obtain an antibacterial antistatic dispersion liquid.

By adopting the technical scheme, the metal stearate and the phosphite ester are added into the nano titanium dioxide, the ultraviolet absorber and the nano graphene oxide, the activated antibacterial agent capable of further improving the antibacterial performance of the fabric is prepared, then the antibacterial agent is uniformly mixed with the antistatic agent to prepare the antibacterial antistatic dispersion liquid, and the fabric is treated by adopting the antibacterial antistatic dispersion liquid, so that the fabric can be processed by only one step to obtain the fabric with both the antistatic performance and the antibacterial performance.

Preferably, the metal stearate is one or a combination of more of calcium stearate, zinc stearate, magnesium stearate and ferric stearate.

By adopting the technical scheme, the metal stearate can adopt any one or more of calcium stearate, zinc stearate, magnesium stearate and ferric stearate, and can be selected according to actual requirements in the actual production process, so that the cost can be controlled.

Preferably, the ultraviolet light absorber is a benzotriazole ultraviolet light absorber, and the benzotriazole ultraviolet light absorber is any one or a combination of more of UV-320, UV-326, UV-327, UV-328, UV-510 and UV-5411.

By adopting the technical scheme, the ultraviolet absorber adopts the benzotriazole ultraviolet absorber, and the ultraviolet absorber and the phosphite ester have a synergistic effect, so that the easy ignition performance of the antibacterial antistatic fabric can be effectively improved.

Preferably, the diatomite has an average particle size of 4.5-5.5 nm.

By adopting the technical scheme, when the average particle size of the diatomite is 4.5-5.5nm, the surface resistivity of the antibacterial antistatic fabric is further reduced, namely the antistatic performance of the antibacterial antistatic fabric is further improved.

Preferably, the dispersant is one or a combination of more of polyethylene glycol 200 and polyethylene glycol 400.

By adopting the technical scheme, the polyethylene glycol 200 or the polyethylene glycol 400 can uniformly mix the antibacterial agent and the antistatic agent to form the antibacterial antistatic dispersion liquid with good dispersion performance, so that the fabric has good antibacterial and antistatic performance.

In a second aspect, the application provides an antibacterial and antistatic fabric, which adopts the following technical scheme:

an antibacterial and antistatic fabric is prepared by any one of the preparation methods of the antibacterial and antistatic fabric.

By adopting the technical scheme, the antibacterial and antistatic fabric with both antibacterial performance and antistatic performance can be obtained, the harm of static electricity to a human body is reduced, and the problem that the fabric is easy to breed bacteria to cause odor or bacterial spots is solved.

In summary, the present application has the following beneficial effects:

1. due to the adoption of the diatomite with good moisture absorption performance, static electricity generated by the fabric can be quickly leaked out, and due to the addition of the silver nitrate, the conductive capacity of the fabric can be further improved, and the antistatic performance of the fabric is improved; in addition, the nanometer titanium dioxide and the ultraviolet absorber have a synergistic effect, so that the antibacterial performance of the fabric can be enhanced, the fabric has the advantages of good antistatic performance and good antibacterial performance, the harm of static electricity to a human body is reduced, and the problem that the fabric is easy to grow bacteria to cause odor or bacterial spots is solved.

2. The application preferably adds stearic acid metal salt and phosphite ester to the antibacterial antistatic dispersion liquid, wherein, the stearic acid metal salt and the phosphite ester have synergistic effect on the improvement of the stability of the ultraviolet light absorbent, thereby being capable of further enhancing the antibacterial performance of the fabric.

3. The ultraviolet light absorber is preferably a benzotriazole ultraviolet light absorber, and the ultraviolet light absorber and phosphite ester have a synergistic effect and can effectively improve the easy ignition performance of the antibacterial antistatic fabric.

Detailed Description

The present application is further described in detail with reference to examples and comparative examples, wherein the fabrics in the examples and comparative examples are chemical fibers, the present application takes nylon fabrics as an example, and the raw materials involved in the present application are all commercially available.

Examples

TABLE 1 Components and proportions (units/kg) of the antibacterial antistatic dispersions of examples 1 to 7

Example 1

The preparation method of the antibacterial and antistatic fabric comprises the following steps:

s1, feeding the fabric into the antibacterial antistatic dispersion liquid for ultrasonic soaking for 15S, and then taking out to obtain a pretreated fabric;

s2, drying the pretreated fabric until the water content of the pretreated fabric is lower than 85% to obtain the dried pretreated fabric;

s3, drying the pressed and dried pretreated fabric at the temperature of 45 ℃ to obtain the antibacterial and antistatic fabric;

the compounding ratio of the components in the antibacterial and antistatic dispersion liquid in step S1 is as follows according to example 1 in table 1 above:

s1.1, preparing an activated antibacterial agent:

s1.11, ball-milling a mixture of nano titanium dioxide, an ultraviolet light absorber and nano graphene oxide at a ball-milling speed of 250rad/min for 1h to obtain an antibacterial agent; in the embodiment, the ultraviolet light absorbent adopts UV-320;

s1.12, irradiating the antibacterial agent for 30min under ultraviolet light with the wavelength of 280nm to obtain an activated antibacterial agent;

s1.2, preparing an antistatic agent:

s1.21, adding silver nitrate into water, and stirring and dissolving to obtain a silver nitrate solution;

s1.22, adding diatomite with the average particle size of 0.5-1.5nm into a silver nitrate solution, and uniformly stirring to obtain an antistatic agent;

s1.3, preparing an antibacterial antistatic dispersion liquid:

s1.31, adding an activated antibacterial agent and a dispersing agent into an antistatic agent, and dispersing by ultrasonic vibration to obtain an antibacterial antistatic dispersion liquid; in this embodiment, the dispersant is polyethylene glycol 200.

Example 2

The preparation method of the antibacterial and antistatic fabric is different from that of the fabric in the embodiment 1:

(1) in the step S1, ultrasonically soaking the fabric in the antibacterial antistatic dispersion liquid for 30S;

(2) in step S3, drying the pressed and dried pretreated fabric at the temperature of 65 ℃;

(3) the ultraviolet light absorbent in the step S1.11 adopts phenyl salicylate, the ball milling speed is 150rad/min, and the ball milling time is 3 h;

(4) in the step S1.12, the antibacterial agent is irradiated for 60min under ultraviolet light with the wavelength of 315 nm;

(5) step S1.31, polyethylene glycol 400 is adopted as the dispersing agent;

(6) the components and proportions of the antibacterial antistatic dispersion of this example were as described in Table 1 above for example 2.

Example 3

The preparation method of the antibacterial and antistatic fabric is different from that of the fabric in the embodiment 1:

(1) s1.11, performing ball milling on a mixture of nano titanium dioxide, an ultraviolet absorber, a metal stearate and nano graphene oxide, wherein the ball milling speed is 250rad/min, and the ball milling time is 1h to obtain an antibacterial agent; in the embodiment, the ultraviolet light absorbent adopts UV-320; wherein, the metal stearate in the embodiment adopts ferric stearate;

(2) the components and proportions of the antibacterial antistatic dispersion of this example were as described in Table 1 above for example 3.

Example 4

The preparation method of the antibacterial and antistatic fabric is different from that of the fabric in the embodiment 1:

(1) s1.11, performing ball milling on a mixture of nano titanium dioxide, an ultraviolet absorber, phosphite ester and nano graphene oxide at a ball milling speed of 250rad/min for 1h to obtain an antibacterial agent; in the embodiment, the ultraviolet light absorbent adopts UV-320; wherein, the metal stearate in the embodiment adopts ferric stearate;

(2) the components and proportions of the antibacterial antistatic dispersion of this example were as described in Table 1 above for example 4.

Example 5

The preparation method of the antibacterial and antistatic fabric is different from that of the fabric in the embodiment 1:

(1) s1.11, performing ball milling on a mixture of nano titanium dioxide, an ultraviolet absorber, a metal stearate, phosphite ester and nano graphene oxide, wherein the ball milling speed is 250rad/min, and the ball milling time is 1h to obtain an antibacterial agent; in the embodiment, the ultraviolet light absorbent adopts UV-320; wherein, the metal stearate in the embodiment adopts ferric stearate;

(2) the components and proportions of the antibacterial antistatic dispersion of this example were as described in Table 1 above for example 5.

Example 6

The preparation method of the antibacterial and antistatic fabric is different from that of the fabric in the embodiment 5 in that:

(1) the amounts of metal stearate and phosphite used in step S1.11 are different, with particular reference to example 6 in table 1.

Example 7

The preparation method of the antibacterial and antistatic fabric is different from that of the fabric in the embodiment 5 in that:

the components and proportions of the antibacterial antistatic dispersion according to this example were determined in Table 1 above for example 7 using phenyl salicylate as the UV absorber in step S1.11.

Example 8

The preparation method of the antibacterial and antistatic fabric is different from that of the fabric in the embodiment 5 in that:

the diatomaceous earth in step S1.22 has an average particle size of 4.5 to 5.5 nm.

Example 9

The preparation method of the antibacterial and antistatic fabric is different from that of the fabric in the embodiment 5 in that:

the diatomaceous earth in step S1.22 has an average particle size of from 10 to 15 nm.

Comparative example

Comparative example 1

A fabric, the preparation method of which is different from that of the fabric in example 1:

the nano titanium dioxide and the ultraviolet absorbent are respectively replaced by nano graphene oxide with the same quantity.

Comparative example 2

A fabric, the preparation method of which is different from that of the fabric in example 1:

the nano titanium dioxide is replaced by nano graphene oxide with the same quantity.

Comparative example 3

A fabric, the preparation method of which is different from that of the fabric in example 1:

the ultraviolet absorbent is replaced by nano graphene oxide with the same quantity.

Performance test

The bacteriostasis rate is as follows: reference is made to GB/T20944.2-2007 evaluation part 2 of antibacterial properties of textiles: the absorption method is used for measuring the bacteriostasis rate of each group of samples prepared in examples 1-9 and comparative examples 1-3, wherein when the bacteriostasis rate is more than or equal to 90%, the antibacterial and antistatic fabric has the antibacterial effect; when the bacteriostasis rate is more than or equal to 99 percent, the antibacterial and antistatic fabric has a good antibacterial effect.

Surface resistivity: reference is made to GB/T12703.4-2010 "assessment of electrostatic properties of textiles section 4: resistivity measurements of surface resistivity were made on each of the groups of samples prepared in examples 1 to 9 and comparative examples 1 to 3; the temperature of the measuring environment is 25 ℃, and the relative humidity is 50%; wherein, when the surface resistivity of the textile is lower than 1 x 10⁷In the process, the antistatic performance of the textile is A grade, and the smaller the surface resistivity is, the better the antistatic performance of the antibacterial antistatic fabric is.

Average ignition time: the ignition time of each group of samples prepared in examples 1-9 and comparative examples 1-3 is measured by referring to GB/T5455-; wherein, the shorter the average ignition time, the more easily the antibacterial and antistatic fabric is ignited.

TABLE 2 Performance test data

Item	Example 1	Example 2	Example 3	Example 4
					Inhibition rate/%)	91.5	92.2	93.3	91.7
Surface resistivity/omega	3.25*106	3.27*106	3.22*106	3.28*106
					Average ignition time/s	5.4	5.2	4.9	16.8
Item	Example 5	Example 6	Example 7	Example 8
					Inhibition rate/%)	99.4	99.6	99.6	99.5
Surface resistivity/omega	3.21*106	3.19*106	3.23*106	2.69*106
					Ignition time/s	18.3	18.9	6.5	18.5
Item	Example 9	Comparative example 1	Comparative example 2	Comparative example 3
					Inhibition rate/%)	99.3	63.6	68.4	74.9
Surface resistivity/omega	3.22*106	3.25*106	3.27*106	3.24*106
					Average ignition time/s	18.8	5.1	4.8	5.3

As can be seen by combining example 1 and comparative examples 1 to 3, and by combining Table 2, the nano titanium dioxide and the ultraviolet absorber are added simultaneously in example 1, the nano titanium dioxide and the ultraviolet absorber in the comparative example 1 are respectively replaced by the same amount of nano graphene oxide, the nano-titanium dioxide in the comparative example 2 is replaced by the same amount of nano-graphene oxide, the ultraviolet absorber in the comparative example 3 is replaced by the same amount of nano-graphene oxide, as can be seen from the data in Table 2, the bacteriostatic rate of the fabric in example 1 is significantly higher than that of the fabric in comparative examples 1-3, and the surface resistivity of the fabric in the embodiment 1 is not much different from the surface resistivity of the fabric in the comparative examples 1 to 3, which shows that the nano titanium dioxide and the ultraviolet absorber in the application have synergistic effect, and the antibacterial effect of the antibacterial and antistatic fabric can be effectively improved.

It can be seen from the combination of example 1 and examples 3-7 and table 2 that example 3 is based on example 1 and is added with ferric stearate, example 4 is based on example 1 and is added with phosphite, examples 5 and 6 are based on example 1 and are added with ferric stearate and phosphite simultaneously, and example 7 is based on example 5 and is replaced with phenyl salicylate for the ultraviolet light absorber UV-320; wherein, the sum of the total amount of the ferric stearate and the phosphite in the example 5 is equal to the addition amount of the ferric stearate in the example 3 and the addition amount of the phosphite in the example 4; as can be seen from the data in table 2, the bacteriostatic rate of the fabric only with ferric stearate or the fabric only with phosphite is much lower than that of the fabric with ferric stearate and phosphite, which indicates that ferric stearate and phosphite have a synergistic effect, and the antibacterial performance of the fabric can be further improved, so that the fabric has good antibacterial performance and antistatic performance; in addition, it can be seen from table 2 that the average ignition time of the fabric with only iron stearate is much lower than that of the fabric with only phosphite or both iron stearate and phosphite, and when phenyl salicylate is used in example 7 instead of the UV-320, the average ignition time of the fabric in example 7 is also significantly reduced, which indicates that the phosphite and the UV-320 in the present application have a synergistic effect, so that the fabric is not easy to ignite.

As can be seen from the combination of example 5 and examples 8-9 and table 2, the antibacterial and antistatic fabric of example 5 and examples 8-9 is different from each other in the average particle size of diatomite, wherein when the average particle size of diatomite is in the range of 4.5-5.5nm, the surface resistivity of the antibacterial and antistatic fabric is further reduced, that is, the antistatic performance of the antibacterial and antistatic fabric is further improved.

The present embodiment is only for explaining the present application, and it is not limited to the present application, and those skilled in the art can make modifications of the present embodiment without inventive contribution as needed after reading the present specification, but all of them are protected by patent law within the scope of the claims of the present application.

Claims (10)

1. The preparation method of the antibacterial and antistatic fabric is characterized by comprising the following steps of: s1, feeding the fabric into the antibacterial antistatic dispersion liquid, ultrasonically soaking for 15-30S, and taking out to obtain a pretreated fabric;

s2, drying the pretreated fabric until the water content of the pretreated fabric is lower than 85% to obtain the dried pretreated fabric;

s3, drying the pressed and dried pretreated fabric at the temperature of 45-65 ℃ to obtain the antibacterial and antistatic fabric;

the antibacterial antistatic dispersion liquid is prepared from the following raw materials in parts by weight:

nano titanium dioxide: 3-6 parts of

Ultraviolet light absorber: 0.3 to 0.6 portion

Nano graphene oxide: 0.6 to 1 portion

Diatomite: 2-5 parts of

Silver nitrate: 0.05 to 0.1 portion

Water: 50 portions of

Dispersing agent: 0.5-1 part.

2. The preparation method of the antibacterial and antistatic fabric according to claim 1 is characterized in that: the preparation method of the antibacterial antistatic dispersion liquid comprises the following steps:

preparing an activated antibacterial agent:

ball-milling the mixture of the nano titanium dioxide, the ultraviolet absorber and the nano graphene oxide at the ball-milling speed of 150 and 250rad/min for 1-3h to obtain the antibacterial agent;

irradiating the antibacterial agent under ultraviolet light for 30-60min to obtain activated antibacterial agent;

preparing an antistatic agent:

adding silver nitrate into water, and stirring and dissolving to obtain a silver nitrate solution;

adding diatomite into a silver nitrate solution, and uniformly stirring to obtain an antistatic agent;

preparing an antibacterial antistatic dispersion liquid:

adding an activated antibacterial agent and a dispersing agent into an antistatic agent, and dispersing by ultrasonic vibration to obtain an antibacterial antistatic dispersion liquid.

3. The preparation method of the antibacterial and antistatic fabric according to claim 1 is characterized in that: the ultraviolet light absorber is any one or a combination of more of salicylate ultraviolet light absorber, benzophenone ultraviolet light absorber and benzotriazole ultraviolet light absorber.

4. The preparation method of the antibacterial and antistatic fabric according to claim 1 is characterized in that: the antibacterial antistatic dispersion liquid also comprises the following raw materials in parts by weight:

metal salts of stearic acid: 0.8 to 1.2 portions of

Phosphite ester: 1-1.5 parts.

5. The preparation method of the antibacterial and antistatic fabric according to claim 4 is characterized in that: the preparation method of the antibacterial antistatic dispersion liquid comprises the following steps:

preparing an activated antibacterial agent:

ball-milling a mixture of nano titanium dioxide, an ultraviolet absorber, a metal stearate, phosphite ester and nano graphene oxide at the ball-milling speed of 150-250rad/min for 1-3h to obtain an antibacterial agent;

irradiating the antibacterial agent under ultraviolet light for 30-60min to obtain activated antibacterial agent;

preparing an antistatic agent:

adding silver nitrate into water, and stirring and dissolving to obtain a silver nitrate solution;

adding diatomite into a silver nitrate solution, and uniformly stirring to obtain an antistatic agent;

preparing an antibacterial antistatic dispersion liquid:

adding an activated antibacterial agent and a dispersing agent into an antistatic agent, and dispersing by ultrasonic vibration to obtain an antibacterial antistatic dispersion liquid.

6. The preparation method of the antibacterial and antistatic fabric according to claim 4 is characterized in that: the metal stearate is one or more of calcium stearate, zinc stearate, magnesium stearate and ferric stearate.

7. The preparation method of the antibacterial and antistatic fabric according to claim 4 or 5, characterized by comprising the following steps: the ultraviolet light absorber is a benzotriazole ultraviolet light absorber, and the benzotriazole ultraviolet light absorber is any one or a composition of more of UV-320, UV-326, UV-327, UV-328, UV-510 and UV-5411.

8. The preparation method of the antibacterial and antistatic fabric according to claim 1 is characterized in that: the average particle size of the diatomite is 4.5-5.5 nm.

9. The preparation method of the antibacterial and antistatic fabric according to claim 1 is characterized in that: the dispersant is one or a combination of more of polyethylene glycol 200 and polyethylene glycol 400.

10. An antibacterial and antistatic fabric is characterized in that: the antibacterial antistatic fabric is prepared by the preparation method of the antibacterial antistatic fabric as claimed in any one of claims 1 to 9.