JP2922505B1 - Paper containing titanium oxide photocatalyst - Google Patents

Abstract

Abstract: [Object] To attach photocatalytic titanium oxide so as not to fall off. In particular, even when used for direct contact with the hand,
Ensure that the photocatalytic titanium oxide does not fall off. The paper 1 containing titanium oxide photocatalyst has fine particles of titanium oxide photocatalyst adhered to the surface of the fiber. On one or both sides of the base sheet 2 containing the photocatalytic titanium oxide, a topsheet 3 having air permeability and light permeability, in which fibers are gathered three-dimensionally and their intersections are bonded, is laminated.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a paper containing a photocatalytic titanium oxide.

[0002]

2. Description of the Related Art Paper containing photocatalytic titanium oxide has the ability to be sterilized by receiving light and to deodorize by decomposing malodorous components. Photocatalytic titanium oxide does not adsorb odors and does not deodorize, unlike activated carbon and zeolite. Organic substances are decomposed and deodorized, so the effect lasts for a long time. Photocatalytic titanium oxide is activated by light energy, has the property of oxidatively decomposing organic substances and the like attached to the surface, and has antibacterial properties. Therefore, it is important that a large amount of the photocatalyst titanium oxide is attached to the photocatalyst-containing titanium oxide-containing paper while the surface of the photocatalyst titanium oxide is exposed as much as possible.

The paper to which a large amount of titanium oxide photocatalyst is exposed and adhered is used for, for example, a roll curtain in a room and has a sterilizing effect and a deodorizing effect. However, paper attached so that a large amount of the photocatalytic titanium oxide is exposed has a disadvantage that the photocatalytic titanium oxide easily falls off. Techniques for attaching photocatalytic titanium oxide to fibers are disclosed in, for example,
173805 and JP-A-9-59892. The former publication describes a technique in which a water-soluble inorganic substance is allowed to act, and then insolubilized to adhere photocatalytic titanium oxide to the surface of cellulose pulp. The latter publication describes a technique for producing titanium oxide-containing paper by making fine particles of titanium oxide, an inorganic filler such as sepiolite or silica gel, and organic fibers.

[0004]

The paper in which the photocatalytic titanium oxide is insolubilized and adhered to the surface of the fiber with an inorganic material, and the paper made by adding an inorganic filler are made of an insolubilized inorganic material or an inorganic filler. Protect the surface. Therefore, there is a feature that the photocatalytic titanium oxide can prevent the pulp fiber which is an organic substance from deteriorating. However, the paper containing the photocatalytic titanium oxide described in these publications needs to add a considerable amount of an insolubilized inorganic substance or an inorganic filler in order to prevent the photocatalytic titanium oxide from falling off. For this reason, it is difficult to adhere the photocatalyst titanium oxide so as not to peel off, and when the amount of exposure is increased, there is a disadvantage that the photocatalyst titanium oxide easily falls off the paper.

In particular, when the paper containing titanium oxide photocatalyst described in these publications is used for direct contact with hands or the like, such as a roll curtain, the photocatalyst oxidation titanium oxide adhering to the surface is used. There is also a drawback that titanium easily falls off and its use is limited.

[0006] The present invention has been developed with the object of solving such disadvantages. An important object of the present invention is to allow the photocatalytic titanium oxide to adhere so as not to fall off, and in particular, to be used for direct contact by hand or the like.
An object of the present invention is to provide a photocatalytic titanium oxide-containing paper that can effectively prevent the photocatalytic titanium oxide from falling off.

[0007]

The photocatalytic titanium oxide-containing paper of the present invention has fine photocatalytic titanium oxide adhered to the surface of the fiber. Further, the paper containing titanium oxide photocatalyst according to the first aspect of the present invention has the air permeability and the light, in which fibers are three-dimensionally aggregated and joined at one or both sides of the base sheet 2 containing the titanium oxide photocatalyst. A top sheet 3 having transparency is laminated and bonded.

Further, in the photocatalytic titanium oxide-containing paper according to the second aspect of the present invention, the photocatalytic titanium oxide is attached to the fiber surface of the base sheet 2 in the paper making process. This base sheet 2
Top sheets 3 are laminated on both sides and adhered.

The photocatalytic titanium oxide-containing paper according to the third aspect of the present invention is obtained by impregnating or coating a photocatalytic titanium oxide on a paper-made base sheet 2. Paper containing titanium oxide photocatalyst impregnated with titanium oxide photocatalyst 1
Preferably, the topsheet 3 is laminated and bonded on both sides. The base sheet 2 coated with the photocatalytic titanium oxide can be bonded by laminating the topsheet 3 on one side to which the photocatalytic titanium oxide is adhered.

In the paper containing titanium oxide of photocatalyst according to claim 4 of the present invention, the fibers of the base sheet 2 and the surface sheet 3 are polyester fibers. Polyester fibers have excellent deterioration properties with respect to photocatalytic titanium oxide.

In the paper containing titanium oxide of photocatalyst according to claim 5 of the present invention, paper or nonwoven fabric is used for the top sheet 3.

The photocatalyst-containing titanium oxide-containing paper according to claim 6 of the present invention uses thermoplastic synthetic fibers for the fibers of the base sheet 2 and the topsheet 3 and the thermoplastic synthetic fiber of the base sheet 2 and the topsheet 3. The base sheet 2 and the top sheet 3 are laminated and bonded by heat welding the fibers.

[0013]

Embodiments of the present invention will be described below with reference to the drawings. However, the following examples illustrate the photocatalyst titanium oxide-containing paper for embodying the technical idea of the present invention, and the present invention does not specify the photocatalyst titanium oxide-containing paper as follows.

Further, in this specification, in order to make it easy to understand the claims, the numbers corresponding to the members shown in the embodiments will be referred to as “claims” and “ In the column of “means”. However, the members described in the claims are not limited to the members of the embodiments.

The paper 1 containing titanium oxide photocatalyst shown in FIG.
The topsheet 3 is laminated and adhered to both sides of the base sheet 2. The photocatalytic titanium oxide-containing paper 1 having this structure is added to the photocatalytic titanium oxide in the step of papermaking the base sheet 2, or the photocatalytic titanium oxide is impregnated and added to the base sheet 2 manufactured by papermaking. . As shown in FIG. 2, the base sheet 2 coated with the photocatalyst titanium oxide on one side can be laminated by bonding the photocatalyst titanium oxide on one side where the photocatalyst titanium oxide is adhered. This is because the coating causes the photocatalytic titanium oxide to adhere to one surface of the base sheet 2. However, the photocatalytic titanium oxide-containing paper of the present invention can be coated and adhered by laminating a surface sheet on both sides of the base sheet having the photocatalytic titanium oxide attached thereto.

The base sheet 2 shown in FIGS. 1 and 2 is manufactured by making paper in the following process using the apparatus shown in FIG. Raw material adjustment Fill the pulper with water, charge the fibers and disintegrate. As a raw material for mixing the photocatalytic titanium oxide, the photocatalytic titanium oxide is mixed with the fiber dissociated in the chest, and a fixing agent, an antifoaming agent, and other chemicals are added. Polyester fibers are optimal for the fibers. However, besides polyester fiber, synthetic pulp such as polyethylene or polypropylene or chemical fiber can also be used. The thickness of the fiber is 0.1 to 6 denier, and the average length is 2 to 10 mm. Preferably, the fibers are used in a mixture of a plurality of thick and thin fibers.
If the fiber is too thick, the voids of the fiber become large, the total surface area becomes small, and it becomes impossible to attach a large amount of photocatalytic titanium oxide. On the other hand, if the fibers are too thin, the voids in the fibers become small, making it difficult for air to pass through, and reducing the strength. The base sheet made by mixing different fibers has a sufficient strength, can attach a large amount of photocatalytic titanium oxide, and can control the air permeability and the like by the thickness of the fibers.

As the added photocatalytic titanium oxide, anatase type titanium oxide is suitable. However, rutile type titanium oxide can also be used. Furthermore, all titanium oxides that exhibit photocatalysis can be used. As the photocatalytic titanium oxide, an ultrafine powder or a sol obtained by dispersing the powder in water is used. The photocatalytic titanium oxide has an average particle size of 6 to 30 nm.
And However, those having an average particle size of 8 to 10 nm have excellent catalytic functions. The amount of the titanium oxide photocatalyst is 1 to 80% by weight, preferably 2 to 5% by weight, based on the total weight of the paper.
0% by weight, more preferably 3 to 30 parts by weight, most preferably about 3 to 8 parts by weight. Increasing the amount of titanium oxide photocatalyst improves the ability as a photocatalyst, but increases the cost of raw materials and causes a problem of deterioration of paper fibers due to titanium oxide photocatalyst. Conversely, if the amount of the photocatalyst titanium oxide is small, the ability as a photocatalyst is reduced. Therefore, the addition amount of the titanium oxide photocatalyst is in the above-mentioned range in consideration of required photocatalytic ability and cost.

As the fixing agent, polyacrylamide Acrypers (a fixing agent manufactured by Nitto Chemical Industry Co., Ltd.) is used. Silicone-based KM-80 (a defoaming agent manufactured by Shin-Etsu Chemical Co., Ltd.) is used as the defoaming agent.

Wet Paper Process The raw material liquid produced by adjusting the raw materials is supplied to the raw material tank 4 shown in FIG. In the raw material tank 4,
A circular net 5 whose lower part is immersed in the raw material liquid is provided horizontally. In the illustrated device, two rows of circular nets 5 are provided in parallel. The circular net 5 is rotated in the direction indicated by the arrow. The circular net 5 is provided with a coach roll 6 in contact with the upper side. Coach roll 6
An endless belt-shaped felt 19 is stretched between the belt and the circular net 5. The surface of the felt 19 is rougher than the mesh 5. This is for transferring the fiber which becomes the base sheet adhered to the surface of the circular net 5 by rotating, from the circular net 5 to the surface of the felt 19. The fibers that become the paper-made base sheet have the property of transferring from the surface of the small mesh to the rough surface. The fibers transferred from the circular net 5 to the surface of the felt 19 have photocatalytic titanium oxide adhered to the surface. In the apparatus shown in FIG. 3, the fibers are made thicker by the two rows of the circular net 5 and transferred to the next step. When the paper-made fiber is transported from the couch roll 6 by the feed roll 7, the contained water is dehydrated to become wet paper. The felt 19 is stretched on the two feed rolls 7. The feed roll 7 dewaters the formed fiber via the felt 19 to form a wet paper.

Drying Step In the apparatus shown in FIG. 3, the wet paper is dehydrated under pressure by two feed rolls 7 and then brought into contact with a series of steam heating cylinders to evaporate residual water. This device is a steam heating cylinder composed of a main roller 8 and an after roller 9, and evaporates the moisture of wet paper as a base sheet.

Winding Step The dried base sheet 2 is wound around a reel 10. In this step, the base sheet 2 having the photocatalytic titanium oxide adhered to the surface of the fiber is manufactured.

As described above, the base sheet 2 on which the photocatalytic titanium oxide is adhered by papermaking is produced in a state in which a large amount of the photocatalytic titanium oxide is adhered and the surface is more efficiently exposed, and the mass is produced inexpensively. There are features that can be done.

Further, the base sheet 2 shown in FIG.
The impregnated paper sheet 2 can be impregnated with titanium oxide photocatalyst using the apparatus shown in FIG. Impregnation Step As shown in FIG. 4, the base sheet 2 is immersed in the dispersion liquid 11 in which the photocatalytic titanium oxide is dispersed, and then the excess liquid is squeezed with two squeezing rolls 12. Dispersion liquid 11 is obtained by adding photocatalytic titanium oxide, a fixing agent, an antifoaming agent, and a pigment to water. A binder is added to the dispersion liquid 11 or not.

Base sheet 2 impregnated with photocatalytic titanium oxide
Is filter paper or nonwoven fabric. Filter paper is prepared by the method described above.
It was manufactured without adding photocatalytic titanium oxide to the raw material liquid. The non-woven fabric is made of a thermoplastic synthetic fiber such as a polyester fiber, and is made into a sheet by a dry method.
As the fiber used for the nonwoven fabric, a thermoplastic synthetic fiber other than the polyester fiber can be used. The nonwoven fabric is manufactured by assembling fibers three-dimensionally and without direction, and connecting intersections of the fibers. The intersections of the fibers are bonded with a binder, or the fibers are bonded by heat welding. As the nonwoven fabric, a commercially available one can also be used.

As the photocatalytic titanium oxide to be added to the dispersion, the same photocatalytic titanium oxide as used for papermaking and adhered to the base sheet 2 can be used. The amount by which the photocatalytic titanium oxide is impregnated into the base sheet 2 is also adjusted to the same amount as that described above for papermaking and adhesion. The impregnation amount of the titanium oxide photocatalyst can be adjusted by the concentration of the titanium oxide photocatalyst added to the dispersion and the pinching force of the squeezing roll.
When the concentration of the photocatalytic titanium oxide in the dispersion liquid is increased and the pinching force of the squeezing roll is reduced, the amount of the photocatalytic titanium oxide impregnated increases. Conversely, when the concentration of the photocatalytic titanium oxide is reduced and the pinching force of the squeezing roll is increased, the impregnation amount of the photocatalytic titanium oxide decreases.

As the fixing agent, the defoaming agent and the pigment to be added to the dispersion, the same raw material liquid as used for producing the base sheet 2 by papermaking is used. That is, polyacrylamide Acrypers (fixing agent manufactured by Nitto Chemical Industry Co., Ltd.) is used as the fixing agent.
As a defoaming agent, a silicone-based KM-80 (a defoaming agent manufactured by Shin-Etsu Chemical Co., Ltd.) is used. The antifoaming agent reduces the foaming of the dispersion and uniformly disperses the photocatalytic titanium oxide. The function of the defoaming agent is the same as that of the defoaming agent added to the raw material liquid for making the base sheet 2 by making paper.

An acrylic or urethane-based binder can be added to the dispersion. When a binder is added to the dispersion, the photocatalytic titanium oxide can be more firmly attached to the surface of the fiber. However, when the binder covers the surface of the photocatalytic titanium oxide, the ability of the photocatalytic titanium oxide is reduced. Therefore, the amount of the binder added is as small as possible.

Drying Step After the base sheet 2 impregnated with the photocatalytic titanium oxide is passed through a through dryer 13, the base sheet 2 is brought into contact with the surface of the cylinder 14 heated by steam to be dried.

Winding Step The dried base sheet 2 is wound around a reel 15. In this step, the base sheet 2 having the photocatalytic titanium oxide adhered to the surface of the fiber is manufactured.

As described above, the method of impregnating paper or non-woven fabric with photocatalytic titanium oxide is as follows. The filter sheet or non-woven fabric, etc., which has already been manufactured, can be used to reduce the cost of the base sheet 2 to which photocatalytic titanium oxide is added. It has the feature of mass production.

Further, the base sheet shown in FIG. 2 can be coated with titanium oxide photocatalyst on the base sheet 2 made by using the apparatus shown in FIG. Coating Step As shown in FIG. 5, the lower surface of the base sheet 2 is brought into contact with a coating roll 16 whose lower part is immersed in a dispersion liquid 11 in which photocatalytic titanium oxide is dispersed. Then, the base sheet 2
Air is blown on the surface of the substrate in the manner indicated by the arrow to remove excess dispersion. The dispersion uses the same dispersion used to impregnate the photocatalytic titanium oxide. The base sheet 2 coated with the photocatalytic titanium oxide is also a filter paper or a nonwoven fabric, which is the same as that to be impregnated.

The amount of the titanium oxide photocatalyst coated and adhered to the base sheet 2 can be adjusted by the concentration of the titanium oxide photocatalyst added to the dispersion and the injection pressure of air. When the concentration of the photocatalyst titanium oxide in the dispersion is increased and the injection pressure of the air is decreased, the amount of the titanium oxide photocatalyst attached increases.
Conversely, when the concentration of the photocatalytic titanium oxide is reduced and the injection pressure of the air is increased, the impregnation amount of the photocatalytic titanium oxide decreases.

In the apparatus shown in FIG. 5, only one surface of the lower surface of the base sheet 2 is coated with the dispersion liquid.
Can be coated with a dispersion on both sides. Photocatalytic titanium oxide is attached to both sides of the base sheet 2 having both sides coated with the dispersion. Therefore, as shown in FIG. 1, the base sheet 2 is formed by laminating and adhering the top sheets 3 on both sides of the base sheet 2.

Thereafter, a drying step and a winding step are performed in the same manner as in the case of impregnating and attaching the titanium oxide photocatalyst, and the base sheet 2 having the titanium oxide photocatalyst adhered to the surface of the fiber is manufactured. You.

The topsheet to be laminated and adhered to the base sheet is manufactured by the same method as that for manufacturing the base sheet by papermaking except that no photocatalytic titanium oxide is added. Also,
A commercially available filter paper or nonwoven fabric can also be used. The filter paper or nonwoven fabric used as the topsheet preferably has polyester fibers as the fibers. This is because deterioration by the photocatalytic titanium oxide is small. However, filter paper or non-woven fabric of fibers other than polyester fibers can also be used.

The base sheet and the top sheet are laminated and bonded using the apparatus shown in FIG. The apparatus shown in this figure has a structure in which both surfaces of a base sheet 2 on which photocatalytic titanium oxide is adhered,
The top sheets 3 are stacked and heated by the preheating rolls 17, then sandwiched by two heating rolls 18, and the three sheets are laminated and wound on a reel.

[0037]

[Example 1] A paper containing titanium oxide photocatalyst is manufactured by the following steps. A. A base sheet is manufactured in the following steps. Raw material adjustment Polyester fiber, photocatalytic titanium oxide, a fixing agent, an antifoaming agent, and a pigment are added to water to adjust a raw material liquid. The polyester fiber has an average length of 3 mm and a mixture of three types of fibers having a thickness of 0.1d, 1.5d, and 3d in an equal amount. As the photocatalytic titanium oxide, an anatase type titanium oxide having an average particle size of 8 to 10 nm is used. As a fixing agent, polyacrylamide Acrypers (a fixing agent manufactured by Nitto Chemical Industry Co., Ltd.) is used, and as a defoaming agent, a silicon-based KM-80 (an antifoaming agent manufactured by Shin-Etsu Chemical Co., Ltd.) is used. .

The amount of the polyester fiber, the fixing agent and the defoamer added to water was 0.8 to 100 parts by weight of water.
Parts by weight of polyester fiber, 0.05 parts by weight of fixing agent, and 0.0016 parts by weight of defoamer. In the raw material liquid, the concentration of the polyester fiber, the photocatalytic titanium oxide, the fixing agent and the antifoaming agent decreases as the paper is made. Keep at a concentration of The amount of the photocatalytic titanium oxide added to the raw material liquid is adjusted to be about 20 parts by weight with respect to 100 parts by weight of the polyester fiber.

Wet paper process The web 5 whose lower part is immersed in the raw material liquid is rotated in the direction of the arrow to transfer the paper-made fibers from the web 5 to the couch roll 6. The fibers transferred from the circular net 5 to the surface of the coach roll 6 have photocatalytic titanium oxide adhered to the surface. 2
The fiber is made thick by the circular net 5 and the couches roll 6 in a row and transferred to the next step. When the paper-made fiber is transported by the feed roll 7, the contained water is dehydrated to be a wet paper.

Drying Step After the wet paper is dehydrated under pressure by the feed roll 7, the residual water is evaporated by a steam heating cylinder to obtain the base sheet 2 to which the photocatalytic titanium oxide is added.

Through the above steps, a base sheet having an added amount of photocatalytic titanium oxide of 15% by weight and a basis weight of 50 g / m ² is manufactured.

B. The top sheet is manufactured in the following steps. Photocatalytic titanium oxide was not added to the raw material liquid, and the grammage was 3
Except for 0 g / m ² , in the same manner as the base sheet,
A topsheet made of polyester fiber is manufactured.

C. Step of Laminating and Adhering Top Sheets on Both Sides of Base Sheet The top sheets 3 are stacked on both sides of the base sheet 2 manufactured in the step A, and the base sheet is laminated using the apparatus shown in FIG. The material sheet 2 and the topsheet 3 are bonded by heat welding. The heat roll for thermally welding the base sheet 2 and the top sheet 3 is:
The surface temperature is set to 230 ° C., and the fibers of the base sheet 2 and the surface sheet 3 are heat-welded at intersections.

In the above steps, the basis weight is 109 g / m ² , the thickness is 0.145 mm, and the tensile strength is 4.6 kg / 15 m.
m, and a photocatalytic titanium oxide-containing paper 1 having an air permeability of 21.6 seconds was obtained. When the sterilization rate of the photocatalytic titanium oxide-containing paper was measured by a shake flask method, E. coli (E.
Coli) and staphylococci (S. aureus). In addition, the paper containing the photocatalytic titanium oxide was placed in a plastic bag, and the cigarette smoke was injected and sealed, and when irradiated with ultraviolet light with black light, the smell of tobacco disappeared and the dirt attached to the photocatalytic titanium oxide-containing paper was almost completely eliminated. did. For comparison, the bag containing the paper to which no photocatalytic titanium oxide was added had a smell of tobacco, and the stain on the surface was not eliminated. In addition, paper to which photocatalytic titanium oxide is added,
When no ultraviolet light was applied, as in the case of paper without the addition of titanium oxide photocatalyst, there was a smell of tobacco, and the stain on the surface was not eliminated.

Example 2 The amount of the titanium oxide photocatalyst was changed from 15% by weight in Example 1 to 3% by weight, 5% by weight,
A photocatalytic titanium oxide-containing paper was trial-produced in the same manner as in Example 1 except that the content was 10% by weight, 20% by weight, and 50% by weight. This photocatalytic titanium oxide-containing paper 1 also exhibited excellent sterilization rates against E. coli and S. aureus, similarly to the photocatalytic titanium oxide-containing paper of Example 1. In addition, the paper containing the titanium oxide photocatalyst was placed in a plastic bag, and the tobacco smoke was injected and sealed, and irradiated with ultraviolet light using black light. Was. In particular, in the photocatalyst titanium oxide-containing paper 1 in which the amount of the photocatalytic titanium oxide added was 10% by weight or more, dirt on the surface of the photocatalyst titanium oxide-containing paper 1 was almost completely eliminated.

Example 3 A base sheet was prepared without adding the photocatalytic titanium oxide to the raw material liquid.
A photocatalytic titanium oxide-containing paper was produced in the same manner as in Example 1 except that coating was performed by adjusting the concentration of the dispersion so that 15% by weight of the photocatalytic titanium oxide adhered. This photocatalytic titanium oxide-containing paper was produced in the same manner as the prototype produced in Example 1 and used for E. coli and S. aurea.
us). The paper containing the photocatalytic titanium oxide was placed in a plastic bag, and the cigarette smoke was injected into the bag, sealed, and irradiated with ultraviolet light using a black light. Resolved.

Example 4 The addition amount of the photocatalytic titanium oxide was changed from 15% by weight of Example 3 to 3% by weight, 5% by weight,
A photocatalytic titanium oxide-containing paper was trial-produced in the same manner as in Example 3 except that the content was changed to 10% by weight, 20% by weight, and 50% by weight. This photocatalytic titanium oxide-containing paper also exhibited excellent sterilization rates against E. coli and S. aureus, similarly to the photocatalytic titanium oxide-containing paper of Example 1.
In addition, the created photocatalytic titanium oxide-containing paper was placed in a plastic bag, tobacco smoke was injected and sealed, and when irradiated with ultraviolet light with black light, the smell of tobacco disappeared and the dirt attached to the photocatalytic titanium oxide-containing paper was reduced. Was. In particular,
In the photocatalyst titanium oxide-containing paper 1 in which the addition amount of the photocatalytic titanium oxide was 10% by weight or more, dirt on the surface of the photocatalyst titanium oxide-containing paper was almost completely eliminated.

Example 5 A substrate sheet was prepared without adding photocatalytic titanium oxide to the raw material liquid.
The concentration of the dispersion was adjusted so that 15% by weight of the photocatalytic titanium oxide adhered, and the surface of the base sheet 2 was applied with a coating roll using the apparatus shown in FIG. A photocatalytic titanium oxide-containing paper was prototyped in the same manner as in Example 1, except that the topsheet 3 was laminated and adhered. This paper containing titanium oxide photocatalyst showed an excellent sterilization rate against Escherichia coli (E. Coli) and staphylococci (S. aureus), similarly to the prototype produced in Example 1. Also,
The produced photocatalytic titanium oxide-containing paper was placed in a plastic bag, tobacco smoke was injected and sealed, and then irradiated with ultraviolet light using black light. As a result, the smell of tobacco disappeared, and dirt attached to the photocatalytic titanium oxide-containing paper was almost completely eliminated.

Example 6 The amount of the titanium oxide photocatalyst was changed from 15% by weight in Example 5 to 3% by weight, 5% by weight,
A photocatalytic titanium oxide-containing paper was prepared in the same manner as in Example 5, except that 10% by weight, 20% by weight, and 50% by weight were used, and a nonwoven fabric of a polyester fiber having a fiber thickness of 3d was used for the topsheet. Prototype made. This photocatalytic titanium oxide-containing paper also exhibited excellent sterilization rates against E. coli and S. aureus, similarly to the photocatalytic titanium oxide-containing paper of Example 1. In addition, the created photocatalytic titanium oxide-containing paper was placed in a plastic bag, tobacco smoke was injected and sealed, and when irradiated with ultraviolet light with black light, the smell of tobacco disappeared and the dirt attached to the photocatalytic titanium oxide-containing paper was reduced. Was. In particular, in the paper containing the titanium oxide photocatalyst containing 10% by weight or more of the titanium oxide photocatalyst, the stain on the surface of the titanium oxide photocatalyst-containing paper was almost completely eliminated.

The paper containing the titanium oxide photocatalyst of the above embodiment uses polyester fiber as the fiber. Polyester fiber has the feature that deterioration due to photocatalytic titanium oxide can be reduced. For this reason, there is a feature that a decrease in strength can be reduced even after long-term use. However, the photocatalytic titanium oxide-containing paper of the present invention uses fibers other than polyester fibers,
It can also be manufactured.

[0051]

The paper containing the titanium oxide photocatalyst of the present invention can be adhered so that the titanium oxide photocatalyst does not fall off. In particular, there is a feature that the photocatalytic titanium oxide can be effectively prevented from falling off even when it is used for a roll curtain or the like that comes into direct contact with the hand or the like. This is because the photocatalyst titanium oxide-containing paper of the present invention is obtained by adding a photocatalytic titanium oxide to a base sheet, and on one or both sides of the base sheet, the fibers are three-dimensionally aggregated and the intersections are bonded to each other to provide air permeability and light. This is because the transparent top sheets are laminated and adhered. Since the photocatalytic titanium oxide-containing paper of this structure protects the base sheet with the topsheet and prevents the photocatalytic titanium oxide from falling off, a large amount of photocatalytic titanium oxide is added to the base sheet to effectively prevent the falling off There are features that can be done. Furthermore, since the topsheet 3 that protects the surface of the base sheet has air permeability and light transmittance, a decrease in the action of the titanium oxide photocatalyst due to this topsheet can be minimized. The fact that a large amount of photocatalytic titanium oxide can be added to the base sheet and the fact that the surface sheet does not reduce the action of the photocatalytic titanium oxide are synergistic, and the photocatalyst titanium oxide-containing paper of the present invention allows the photocatalytic titanium oxide to act effectively. It effectively sterilizes or realizes excellent effects such as deodorization.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view showing a laminated structure of a photocatalytic titanium oxide-containing paper according to an embodiment of the present invention.

FIG. 2 is a sectional view showing a laminated structure of a photocatalytic titanium oxide-containing paper according to an embodiment of the present invention.

FIG. 3 is a schematic cross-sectional view of an apparatus for producing a base sheet used for the photocatalytic titanium oxide-containing paper of the present invention.

FIG. 4 is a schematic sectional view of an apparatus for producing a base sheet used for the photocatalytic titanium oxide-containing paper of the present invention.

FIG. 5 is a schematic sectional view of an apparatus for producing a base sheet used for the photocatalytic titanium oxide-containing paper of the present invention.

FIG. 6 is a schematic sectional view showing an apparatus for laminating and bonding a base sheet and a topsheet.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Paper containing titanium oxide photocatalyst 2 ... Base sheet 3 ... Surface sheet 4 ... Raw material tank 5 ... Circle net 6 ... Couch roll 7 ... Feed roll 8 ... Main roller 9 ... After roller 10 ... Reel 11 ... Dispersion liquid 12 ... Squeeze roll 13 ... Thru dryer 14 ... Cylinder 15 ... Reel 16 ... Coating roll 17 ... Preheating roll 18 ... Heat roll 19 ... Felt

Claims (6)

(57) [Claims] 1. A photocatalytic titanium oxide-containing paper in which fine particles of photocatalytic titanium oxide are adhered to the surface of a fiber, wherein the fibers are three-dimensionally assembled on one or both surfaces of a base sheet (2) containing the photocatalytic titanium oxide. A photocatalytic titanium oxide-containing paper characterized by being laminated and bonded with a top sheet (3) having air permeability and light transmissivity, which is connected to intersections. 2. A photocatalytic titanium oxide is attached to the fiber surface of a base sheet (2) in a paper making step, and a topsheet (3) is laminated and adhered to both sides of the base sheet (2). 2. The paper containing titanium oxide photocatalyst according to 1. 3. The titanium oxide photocatalyst-containing paper according to claim 1, wherein the titanium oxide photocatalyst is impregnated or coated on the paper-made base sheet (2). 4. The paper containing titanium oxide photocatalyst according to claim 1, wherein the fibers of the base sheet (2) and the surface sheet (3) are polyester fibers. 5. The paper containing titanium oxide photocatalyst according to claim 1, wherein the topsheet (3) is paper or nonwoven fabric. 6. The fibers of the base sheet (2) and the top sheet (3) are thermoplastic synthetic fibers, and the base sheet (2) and the top sheet (3) are made of thermoplastic synthetic fibers.
2. The photocatalyst-containing titanium oxide-containing paper according to claim 1, wherein the paper is laminated by heat welding.