JPH09154925A - Functional mesh sheet, deodorant element and deodorizing apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To achieve easier arrival of light in the form of a deodorant element, a development of a better deodorizing capacity, a smaller bulk and a minimization of manufacturing costs and a prevention of aging when paper is used as a base material sheet by arranging the base material sheet and functional titanium oxide to prepare a material. SOLUTION: A number of intermittent slits (1b) are formed on a base sheet (1a) to make a widening mesh sheet 1. Functional titanium oxide (T) comprising superfine titanium oxide (t) with the an X-ray particle size of at most 100nm or modified superfine titanium oxide (t') with the surface thereof (t) modified by a metal or a metal compound is supported on the base material sheet (1a). The functional mesh sheet thus obtained is fixed being widened to make a deodorant element and assembled together with an ultraviolet lamp to build a deodorizing apparatus.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a functional mesh sheet comprising a functional titanium oxide-carrying expandable mesh sheet, a deodorizing element and a deodorizing device using the functional mesh sheet.

[0002]

2. Description of the Related Art As a filter for removing odorous components, impure components, dust, etc. in a gas atmosphere, a deodorizing filter equipped with an air conditioner in which activated carbon is wrapped in a non-woven fabric or a net is conventionally used.

Japanese Patent Laid-Open No. 59-69125 discloses, as one method for cleaning air, winding crepe or embossed paper into a roll and, if necessary, using a roll of paper and paper. In between, or in the paper, intervene chemicals such as deodorants (activated carbon, deodorants, fragrances, desiccants, etc.) and perform cleaning while passing air from one end face of this winding roll to the other end face. A method of seeking is disclosed.

JP-A-56-15828 and JP-A-5-
In JP-A-6-16097 and JP-A-57-102221, one or both of a flat sheet material and a corrugated sheet material are made of activated carbon fiber-containing paper to remove odor in a gas to be treated. , A deodorizing element formed by stacking both sheet materials is disclosed.

Although it does not relate to deodorization, it is disclosed in Japanese Patent Laid-Open No. 55-55
JP-A-159827 discloses a dehumidifying body in which a honeycomb structure having a large number of parallel gas passages impregnated with a water absorbent (lithium chloride etc.) is stage-processed from a paper containing an adsorbent (activated carbon etc.). There is disclosed a dehumidifying device for a moist gas containing a.

Japanese Utility Model Laid-Open No. 62-11 filed by the present applicant
Japanese Patent No. 4621 uses non-combustible paper as a sheet material when a corrugated cardboard obtained by laminating a flat sheet and a corrugated sheet is laminated in multiple layers to form a laminate having a large number of parallel through holes. A laminated structure for gas treatment is shown, in which an extract or dry-distillate of Camellia plants is attached to non-combustible paper.

[0007] Similarly, the actual application of the applicant's application 4-
No. 106624 discloses a corrugated cardboard obtained by laminating a flat sheet and a corrugated sheet with a corrugator to form a multilayer laminate having a large number of parallel through holes, and through which the through holes of this laminate are passed. In a filter that performs gas treatment by allowing gas to pass, a deodorizing filter in which semi-carbazide as a deodorizing active ingredient is attached to the above honeycomb-shaped laminate is disclosed.

From another standpoint different from the above,
Recently, ultrafine titanium oxide with photocatalytic function is used for photodeodorization (tobacco odor, daily odor, body odor, etc.), air purification (NOx, trichloroethane, etc.), stain decomposition (cigarette tar, oils, etc.), antibacterial (hygiene It has been reported that it is effective in improving or purifying water quality (pottery, tiles, etc.). For example,
"Electrochemistry and Industrial Physical Chemistry, 68 , No. 1, p. 9-13
(1995), published by The Electrochemical Society of Japan "," Nikkei Business, March 21, 1994, pages 60-61 ".

It has also been reported that wood pulp is dispersed in water to form a slurry, and a titanium oxide sol which has been agglomerated beforehand with aluminum hydroxide is added to the paper for papermaking.

[0010]

Among the above-mentioned conventional techniques, ultrafine titanium oxide having a photocatalytic function is activated by light energy and has a function of oxidizing and decomposing many organic harmful substances and malodorous substances. The application to the deodorizing filter is considered.

Therefore, the present inventors have added ultrafine titanium oxide to the paper by adding it in the papermaking process, and wound the contained paper into a roll or made corrugated cardboard from the contained paper into multiple stages. Various studies were conducted on stacking, then cutting to a predetermined thickness and applying it to a deodorizing element such as an air conditioner, but such a deodorizing element had the following problem to be solved.

That is, this deodorizing element is (a)
Since it has a predetermined thickness, when incorporated into an air conditioner or the like, the light from the ultraviolet lamp does not reach the eyes of the deodorizing element sufficiently, and deodorization by the photocatalytic function cannot be achieved as expected ( B) Since it has a certain thickness, it is bulky, and the depth of the air conditioner, etc. is correspondingly large.
(C) Since the process until the deodorizing element is manufactured becomes long,
There is a limit to the control of manufacturing costs, and (d) the ultrafine titanium oxide contained in the paper oxidizes and decomposes not only the malodorous substance but also the pulp itself, which is the support, in a short period of time. There were still problems to be solved, such as significant deterioration.

Regarding the above-mentioned (d) deterioration of paper, a titanium oxide sol which has been agglomerated with aluminum hydroxide in advance is used, or an inorganic filler having a small adsorptive fixing ability and an ultrafine titanium oxide are used as an aggregating agent. The test was also conducted on the co-aggregated product, but the deterioration was improved to some extent.

Under the circumstances, the present invention is a material using a base sheet and a functional titanium oxide,
When used as a deodorizing element, light can easily reach it, thus exhibiting good deodorizing ability, small bulk, minimizing manufacturing cost, and preventing deterioration even when paper is used as the base sheet. The purpose of the present invention is to provide a functional mesh sheet that can be manufactured. Moreover, it aims at providing the deodorizing element and the deodorizing apparatus which used the functional mesh sheet.

[0015]

The functional mesh sheet of the present invention is a mesh sheet (1) capable of widening in which a large number of intermittent slits (1b) are provided in a base material sheet (1a), The material sheet (1a) includes ultrafine titanium oxide (t) having an X-ray particle size of 100 nm or less, or modified ultrafine titanium oxide obtained by modifying the surface of the ultrafine titanium oxide (t) with a metal or a metal compound.
It is characterized in that a functional titanium oxide (T) composed of (t ') is supported. In this case, the wide mesh sheet (1) was provided with a large number of interrupt slits (1b) in parallel on the base material sheet (1a), and the slit positions of adjacent interrupt slits (1b) were shifted from each other. It is particularly preferable that it has a shape.

The deodorizing element of the present invention is obtained by fixing the above functional mesh sheet in a widened state.

The deodorizing device of the present invention incorporates the above deodorizing element and an ultraviolet lamp.

[0018]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below in detail.

<Functional Mesh Sheet> The mesh sheet (1) used in the present invention is an expandable mesh sheet in which a large number of intermittent slits (1b) are provided in the base material sheet (1a). To facilitate widening, a large number of interrupt slits (1b) are arranged in parallel on the base sheet (1a) and adjacent interrupt slits.
It is preferable that the slit positions of (1b) are provided so that the slit positions are displaced from each other.

As the substrate sheet (1a), a single-layer or multi-layer sheet made of at least one of paper, non-woven fabric, resin layer or metal foil is used, and paper is particularly important. Examples of multi-layer sheets are paper / paper, paper / resin layer, paper / metal foil, resin layer / resin layer, metal foil / resin layer, and the like.

The above base sheet (1a) is modified by modifying the surface of ultrafine titanium oxide (t) having an X-ray particle size of 100 nm or less or the surface of the ultrafine titanium oxide (t) with a metal or a metal compound. Functional titanium oxide (T) composed of ultrafine titanium oxide (t ') is supported. The supported amount is appropriately determined. The base sheet (1a) can also carry other chemicals or humidity control agents.

Supporting of the functional titanium oxide (T) is carried out by internal addition to the base sheet (1a) (internal addition during sheet production), coating (coating, spraying, dipping, etc.). In the case of coating, depending on the coating method, the base sheet (1a) has an intermittent slit (1b).
It is also possible to perform coating after the provision of, or even after widening.

Here, as the ultrafine titanium oxide (t), X
A linear particle size (calculated by Scherrer's formula) of 100 nm or less is used. The preferred range of X-ray particle size is 2 to 50 n
m, a particularly preferred range is 3 to 30 nm. Such ultrafine titanium oxide generally has a photocatalytic function. The crystal form of ultrafine titanium oxide (t) is often an anatase form, but it may be a rutile form. Ultrafine titanium oxide (t) is available in the form of powder or sol and is usually used in the form of powder (BET specific surface area at this time is 150
m ² / g or more, particularly 180 m ² / g or more, more preferably 200 m ² / g or more), or a sol.

The above ultrafine titanium oxide (t) can be used as it is for the purpose of the present invention, but its surface is modified with a metal or a metal compound to obtain modified ultrafine titanium oxide.
(t ') is more suitable for the purpose of the present invention because the deodorizing performance is further enhanced. Examples of the metal or metal compound as the modifier include metals such as gold, silver, copper, platinum, zinc, silicon and iron, and oxides and hydroxides of these metals. A particularly preferred modifier is zinc oxide (or zinc oxide and silicon oxide). The modification can be carried out by various methods, for example, JP-A-6-19.
The method described in Japanese Patent Publication No. 9524 can be adopted.
As an example of modification with zinc oxide, a dispersion of ultrafine titanium oxide (t), a zinc salt such as zinc chloride, zinc sulfate, or zinc nitrate, and an aqueous solution of an alkaline substance are mixed,
Then, it is neutralized to be precipitated, washed if necessary, and dried.

In the modified ultrafine titanium oxide (t '), the weight ratio of the ultrafine titanium oxide (t) to the modifier metal or metal compound is usually 65:35 to 99: 1, preferably 70 :. 30-98: 2, more preferably 75:25
To 97: 3. When the proportion of the modifier is less than this range, the deodorizing effect due to the modification is less improved, while when the proportion of the modifier is too large, the deodorizing effect is rather reduced.

Since it is particularly desirable that the base material sheet (1a) carrying the functional titanium oxide (T) is a papermaking product (paper), a more detailed description of this papermaking product will be given below. To do.

This papermaking product contains functional titanium oxide (T) and
It is composed of a papermaking product (that is, paper) containing an inorganic filler (F) for supporting the functional titanium oxide (T) and an organic fibrous material (P) having a papermaking ability as essential constituents.

The inorganic filler (F) is a functional titanium oxide.
Although it is for supporting (T), since general inorganic fillers have a large difference in the ability to adsorb and fix functional titanium oxide (T), sepiolite, silica gel, bentonite, zeolite, magnesium sulfate, asbestos and It is desirable to use at least one selected from the group consisting of activated carbon (especially sepiolite is important). By using such a specific filler, the content of the functional titanium oxide (T) in the paper can be significantly improved. The inorganic filler (F) may be in the form of powder, fibers close to fine powder, or whiskers.

Functional inorganic oxide of the above inorganic filler (F)
The adsorptive fixing ability of (T) can be confirmed by the aggregation rate and the aggregation state when both are mixed in water. It can also be confirmed by observing the paper after paper making under a high magnification (about 1000 to 3000 times) with a microscope. The fixing ability here means that the filler itself has the ability to adsorb and fix the functional titanium oxide (T) .Thus, if the fixing agent or coagulant is forcibly fixed, the titanium oxide will fall off over time. Tends to occur, and a preferable result tends not to be obtained.

Inorganic substances such as aluminum hydroxide, kaolin, calcium carbonate, and talc have a small ability to adsorb and fix functional titanium oxide (T), so that they can be used in combination, but the above inorganic fillers can be used together. It has almost no alternative meaning of (F).

As the organic fibrous material (P) having a papermaking ability, normal pulp is preferably used, but other organic fibrous materials can be used as long as they have a papermaking ability.

In making paper, the above-mentioned functional titanium oxide (T), inorganic filler (F), and organic fibrous material (P) are used.
At the same time, other reinforcing fibers such as glass fiber, ceramic fiber, and synthetic fiber may be added. Further, an organic or inorganic binder may be added in an appropriate amount. In addition, various auxiliaries or additives that are added during ordinary papermaking can be added.

The total amount of the functional titanium oxide (T) and the inorganic filler (F) in the entire papermaking product after papermaking is 5 to 90% by weight, especially 10 to 70% by weight, and especially 20 to 60% by weight. % Is preferable. The weight ratio of the functional titanium oxide (T) to the inorganic filler (F) is 0.02 to 20, especially
It is preferably 0.1 to 10, and especially 0.5 to 5. If the amount of functional titanium oxide (T) is too small, the deodorizing effect will be insufficient, and if it exceeds the permissible limit, paper strength will be reduced.
When the inorganic filler (F) is too small, it is difficult to adsorb and fix the required amount of functional titanium oxide (T), and when it is too large, the ratio of functional titanium oxide (T) becomes relatively small. The deodorizing effect and the like will be insufficient accordingly.

The proportion of the organic fibrous material (P) in the entire papermaking product is preferably 5 to 90% by weight, particularly 10 to 60% by weight, and above all 10 to 40% by weight. Too little organic fibrous material (P) leads to a lack of paper strength, while too much leads to a relative decrease in the ratio of functional titanium oxide (T) and inorganic filler (F), and the deodorizing effect is insufficient. become.

The paper is made of the above-mentioned functional titanium oxide (T), inorganic filler (F), and organic fibrous material (P) (reinforcing fibers, binders, auxiliaries, additives, other Deodorizing agent may also be used in combination) in a state of being dispersed in water and subjected to wet papermaking according to a conventional method.

<Deodorizing Element and Deodorizing Device> A deodorizing element can be obtained by fixing the functional mesh sheet composed of the above mesh sheet (1) in a widened state. In order to fix the widened state, it is possible to use an appropriate frame or apply a rough mesh or a perforated thin plate. The functional mesh sheet can be used not only as a single sheet but also as a stack of two or more sheets.

The deodorizing device of the present invention incorporates this deodorizing element and an ultraviolet lamp. The deodorizing device refers to a deodorizing device dedicated to deodorizing, as well as an air conditioner, an air purifier, a dust collector, a dehumidifier, and a blower / exhaust fan. The UV lamp is usually provided on one side of the widened mesh sheet (1) in the widening direction and on the lower side of the inclined ground.

<Operation> Since the base material sheet (1a) is provided with the intermittent slits (1b) as described above, the mesh sheet (1) can be widened, and the widening allows the mesh sheet (1) to be sandwiched by notches. The base portion (1a) changes from a flat surface into a slight three-dimensional shape because the ground portion is inclined. As the degree of widening increases, the angle of inclination (rise angle) increases,
The size of the eyes also increases. Moreover, the slope of the ground is aligned in one direction, so by selecting the installation location of the UV lamp (especially on one side of the expanded mesh sheet (1) in the width direction, In addition to providing the light to the entire surface of the base sheet (1a), it is possible to prevent light from leaking from the widened mesh sheet (1). In addition, widened mesh sheet (1)
Has the advantage that it is not bulky and has a small pressure loss.

The functional titanium oxide (T) carried on the base material sheet (1a) exerts an excellent oxidizing action under the irradiation of light and promptly decomposes the malodor and organic substances which come into contact therewith. At this time, the deodorizing effect is remarkable, and the malodorous components such as hydrogen sulfide and ammonia, which are difficult to be removed by a normal adsorption type deodorant, can be effectively removed. Then, if the deodorizing element of the present invention is used for deodorizing while irradiating with light, or if it is used for deodorizing and then irradiating with light, the deodorizing ability is restored, so that it can be reused repeatedly.

When the functional titanium oxide (T) is a modified ultrafine titanium oxide (t '), the modifier such as zinc oxide once adsorbs and captures the odorous component, and the odorant component due to the ultrafine titanium oxide (t) is absorbed. It is thought to play a role in aiding the oxidative decomposition of. Therefore, as long as the modifying amount of the modifying agent is appropriate, the deodorizing efficiency of the modified ultrafine titanium oxide (t ′) is much higher than that of the ultrafine titanium oxide (t ′).

As the base material sheet (1a) carrying the functional titanium oxide (T), the functional titanium oxide (T) and the inorganic filler (F) for carrying the functional titanium oxide (T) are used. When,
When using a papermaking product containing an organic fibrous material (P) having papermaking ability as an essential component, the inorganic filler (F) plays a role of effectively adsorbing and fixing the functional titanium oxide (T). .
The functional titanium oxide (T) adsorbed and fixed to the inorganic filler (F) exerts an excellent oxidizing action under the irradiation of light, and decomposes the malodor and organic substances that come into contact with the functional titanium oxide (T). To do. In this case, the functional titanium oxide (T) is present in the paper in a state of being adsorbed and fixed on the inorganic filler (F).
The contact area of the functional titanium oxide (T) with the organic fibrous material (P) such as pulp is very small, and the organic fibrous material (P), which is an organic matter, is present even when light irradiation is performed. The deterioration of the papermaking product is extremely small. Further, this papermaking product can be made flame-retardant or non-flammable by selecting the type and amount of each component constituting it.

[0042]

The present invention will be further described with reference to the following examples. Hereinafter, "parts" refers to parts by weight.

Example 1 FIG. 1 is a plan view showing an example of the functional mesh sheet of the present invention. FIG. 2 is a perspective view of the deodorizing element in which the functional mesh sheet is fixed in a widened state. FIG. 3 is a partial cross-sectional view of the deodorizing element of FIG. 2 in the transverse direction. FIG. 4 is a schematic diagram of a deodorizing device incorporating the deodorizing element of FIG.

<Substrate sheet (1a)> Modified ultrafine titanium oxide
As (t ') (an example of functional titanium oxide (T)), titanium oxide "ST-31" for photocatalyst manufactured by Ishihara Sangyo Co., Ltd. (crystal form: anatase, TiO ₂ content of 110 ° C dried product: 81)
% By weight, ZnO content: 14% by weight, X-ray particle size: 7 nm, B
ET specific surface area: 260 m ² / g) 30 parts, inorganic filler (F)
7 parts of sepiolite and 20 activated carbon with a particle size of 10s of μm
Parts, 20 parts of pulp as the organic fibrous material (P), 8 parts of ceramic fibers as reinforcing fibers, 5 parts of alumina sol as binder, 6 parts of latex emulsion and 4 parts of organic fibrous binder, and wet papermaking according to a conventional method. I went. As a result, functional titanium oxide (T)
A base material sheet (1a) carrying was obtained. Basis weight is 171
g / m ² , thickness 0.29 mm, density 0.59 g / cm ³ , tensile strength
It was 2.7 kg / 15 mm. This paper (base sheet (1a))
When exposed to the lighter's fire, it was nonflammable, did not burn, and merely reduced in thickness.

<Functional mesh sheet> While running the base sheet (1a) obtained above, a large number of interrupt slits (1b) were formed in parallel with each other by using a rotary blade, and adjacent interrupt slits (1
The slit positions of b) were formed so that they were displaced from each other. As a result, a functional mesh sheet composed of the mesh sheet (1) capable of widening was obtained. The distance between adjacent interrupt slits (1b) is 2 mm, the length of one unit slit in one line of interrupt slit (1b) is 12 mm, the interval between the slits of one unit (the length of the part where no slit is provided) ) Was 3 mm. Further, the positional relationship between the slits of the adjacent intermittent slits (1b) is made to be complementary as shown in FIG.

<Deodorizing Element and Deodorizing Device> The functional mesh sheet consisting of the mesh sheet (1) obtained above was cut to a predetermined length in the width direction, and then expanded in a width of 1.2 times to 4 times. The surrounding area is fixed with the frame (2), and it is shown in Fig. 2-3.
The deodorizing element (3) was prepared (at this time, one side or both sides can be reinforced by applying a mesh with coarse mesh). Then, the deodorizing element (3) and the ultraviolet lamp (4) were incorporated into an improved domestic air purifier to obtain the deodorizing device shown in FIG.

As shown in FIG. 3, since the ultraviolet rays are irradiated from the direction of the white arrow, the ultraviolet rays hit almost the entire one surface of the deodorizing element (3), and the ultraviolet rays do not leak forward (downward in FIG. 3). . The deodorizing effect when actually used was extremely favorable.

<Deodorization Test 1 / Static Test> The mesh sheet (1) obtained above was cut into a size of 100 mm × 100 mm and curved in a gutter shape, and a 4 W ultraviolet lamp (black light) was used. It was fixed at a distance from the lamp so as to cover (4). The UV lamp (4) with the mesh sheet (1) set in this way was sealed together with the malodorous components (ammonia, acetaldehyde, acetic acid, trimethylamine, methyl mercaptan, hydrogen sulfide, styrene) in a glass container with a stirrer with a volume of 5 liters. , Constant temperature (35-37
After left for a predetermined time at (° C.), the residual gas concentration was measured with a detector tube.

The test results are shown in Tables 1-7. The number of repetitions n was set to 5 (when the result of 0 ppm was obtained three times in succession, it was cut off 3 times), and the average was taken excluding the maximum value and the minimum value to obtain the average value. The removal rate is for the data corresponding to each time of blank test (1 hr, 3 hr, 5 hr).

[0050]

[Table 1] Ammonia time data (ppm) Average value (ppm) Removal rate (%) Blank test 1hr 420, 400, 360, 440, 320 393-3hr 480, 400, 280, 460, 380 413-5hr 380, 400 , 300, 380, 400 387- No UV irradiation 1hr 60, 140, 140, 140, 140 140 64.4 3hr 80, 50, 70, 50, 40 57 86.2 5hr 80, 40, 45, 50, 40 45 88.4 With UV irradiation 1hr 100, 100, 80, 100, 110 100 74.6 3hr 10, 0, 10, 5, 5 7 98.3 5hr 2, 1, 1, 1, 1 1 99.7

[0051]

[Table 2] Acetaldehyde time data (ppm) Average value (ppm) Removal rate (%) Blank test 1hr 450, 750, 375, 375, 500 442-3hr 325, 500, 300, 275, 325 317-5hr 200, 625 , 250, 275, 425 317- No UV irradiation 1hr 75, 125, 60, 100, 125 100 77.4 3hr 25, 70, 70, 125, 50 63 80.1 5hr 70, 88, 50, 50, 25 57 82.0 With UV irradiation 1hr 3, 12, 7, 2, 5 5 98.9 3hr 0, 0, 0 0 100 5hr 0, 0, 0 0 100

[0052]

[Table 3] Acetic acid time data (ppm) Average value (ppm) Removal rate (%) Blank test 1hr 280, 280, 250, 300, 250 270-3hr 400, 330, 300, 310, 390 343-5hr 460, 370 , 340, 390, 300 367- Without UV irradiation 1hr 10, 10, 10, 10, 10 10 96.3 3hr 5, 3, 2, 2, 5 3 99.1 5hr 3, 2, 2, 2, 4 2 99.5 With UV irradiation 1hr 4, 3, 2, 2, 2 2 99.3 3hr 2, 2, 1, 2, 2 2 99.4 5hr 2, 1, 1, 1, 1 1 99.7

[0053]

[Table 4] Trimethylamine time data (ppm) Average value (ppm) Removal rate (%) Blank test 1hr 300, 270, 340, 260, 270 280-3hr 280, 260, 280, 410, 270 277-5hr 300, 230 , 340, 280, 260 280- No UV irradiation 1hr 25, 30, 40, 35, 35 33 88.2 3hr 35, 30, 30, 30, 35 32 88.4 5hr 30, 25, 30, 30, 35 30 89.3 With UV irradiation 1hr 20, 10, 10, 5, 10 10 96.4 3hr 0, 0, 0 0 100 5hr 0, 0, 0 0 100

[0054]

[Table 5] Methyl mercaptan time data (ppm) Average value (ppm) Removal rate (%) Blank test 1hr 200, 290, 250, 220, 230 233-3hr 240, 200, 520, 260, 340 280-5hr 280, 190, 500, 450, 200 310- No UV irradiation 1hr 6, 7, 5, 4, 2 5 97.9 3hr 0, 0, 0 0 100 5hr 0, 0, 0 0 100 UV irradiation 1hr 1, 1, 2, 1, 1 1 99.6 3hr 0, 0, 0 0 100 5hr 0, 0, 0 0 100

[0055]

[Table 6] Hydrogen sulfide time data (ppm) Average value (ppm) Removal rate (%) Blank test 1hr 300, 420, 330, 300, 210 310-3hr 420, 300, 380, 230, 350 343-5hr 290, 240, 320, 250, 360 287- No UV irradiation 1hr 0, 0, 0 0 100 3hr 0, 0, 0 0 100 5hr 0, 0, 0 0 100 UV irradiation 1hr 0, 0, 0 0 100 3hr 0, 0, 0 0 100 5hr 0, 0, 0 0 100

[0056]

[Table 7] Styrene time data (ppm) Average value (ppm) Removal rate (%) Blank test 1hr 440, 580, 640, 560, 400 527-3hr 440, 620, 510, 600, 600 570-5hr 400, 400 , 400, 500, 440 413- No UV irradiation 1hr 10, 10, 10, 10, 10 10 98.1 3hr 5, 5, 0, 0, 5 3 99.5 5hr 0, 0, 0 0 100 UV irradiation 1hr 18, 18 , 18, 15, 20 18 96.6 3hr 5, 5, 5, 5, 5 5 99.1 5hr 0, 0, 0 0 100

From Tables 1 to 7, the deodorizing element using the functional mesh sheet of the present invention has excellent removability of malodorous components without being irradiated with ultraviolet rays. It can be seen that the removability is improved.

<Deodorization Test 2 / Repeat Test> The mesh sheet (1) obtained above was cut into a size of 100 mm × 100 mm and curved in a gutter shape, and a 4 W ultraviolet lamp (black light) ( 4) It was fixed so that it was slightly separated from the lamp so as to cover. The UV lamp (4) with the mesh sheet (1) set in this way was sealed together with the malodorous components (ammonia, acetaldehyde, acetic acid, trimethylamine, methyl mercaptan, hydrogen sulfide, styrene) in a glass container with a stirrer with a volume of 5 liters. , Constant temperature (35-3
After measuring the concentration at 7 ° C for 2 hours, the odorous gas is purged, and thereafter, at a constant temperature (35 to 37 ° C), the odorous gas is injected every 2 hours, the concentration is measured, and the odorous gas is purged. By repeating the above, it was examined whether or not the deodorizing performance was deteriorated.
The residual gas concentration was measured with a detector tube.

The test results are shown in Tables 8 to 14 and FIGS. Removal rates are for blank test. No UV irradiation was performed in the blank test. The third time in Table 10,
The description of the 6th and 8th data is omitted,
FIG. 7 also shows the corresponding data at the 6th, 12th and 16th hours.

[0060]

[Table 8] Ammonia data (ppm) 1st 2nd 3rd 4th 5th 6th Blank test 440 360 400 323 387 330 No UV irradiation 37 137 200 137 187 207 (Removal rate%) 91.6 61.9 50.0 57.6 51.7 37.3 UV Irradiated 7 8 7 11 8 6 (removal rate%) 98.4 97.8 98.3 96.6 97.9 98.2

[0061]

[Table 9] Acetaldehyde data (ppm) 1st 2nd 3rd 4th 5th 6th blank Test 275 340 277 242 280 273 No UV irradiation 37 330 193 183 297 283 (% removal) 86.5 2.9 30.3 24.4 0.0 0.0 UV Irradiated 0 0 1 0 1 0 (removal rate%) 100 100 99.6 100 99.6 100

[0062]

[Table 10] Acetic acid data (ppm) 1st 2nd 4th 5th 7th 9th Blank test 383 380 283 330 203 277 No UV irradiation 5 7 19 46 39 65 (% removal) 98.7 98.2 93.3 86.1 80.8 76.5 UV Irradiated 3 6 4 8 10 20 (removal rate%) 99.2 98.4 98.6 97.6 95.1 92.8

[0063]

[Table 11] Trimethylamine data (ppm) 1st 2nd 3rd 4th 5th 6th Blank test 277 330 277 320 290 300 UV irradiation no 20 63 120 177 190 200 (removal rate%) 92.8 80.9 56.7 44.7 34.5 33.3 UV Irradiated 1 12 33 43 82 110 (Removal rate%) 99.6 96.4 88.1 86.6 71.7 63.3

[0064]

[Table 12] Methyl mercaptan data (ppm) 1st 2nd 3rd 4th 5th 6th Empty test 270 303 260 197 253 280 No UV irradiation 0 13 20 18 31 51 (removal rate%) 100 95.7 92.3 90.9 87.7 81.8 With UV irradiation 0 5 11 11 17 27 (removal rate%) 100 98.3 95.8 94.4 93.3 90.4

[0065]

[Table 13] Hydrogen sulfide data (ppm) 1st 2nd 3rd 4th 5th 6th Blank test 290 317 283 283 300 343 310 No UV irradiation 0 0 0 0 0 0 (removal rate%) 100 100 100 100 100 100 With UV irradiation 0 0 0 0 0 0 (Removal rate%) 100 100 100 100 100 100

[0066]

[Table 14] Styrene data (ppm) 1st 2nd 3rd 4th 5th 6th Blank test 593 510 567 633 470 543 UV No irradiation 2 6 260 320 420 503 (removal rate%) 99.7 98.8 54.1 49.4 10.6 7.4 UV Irradiated 5 6 66 280 297 343 (removal rate%) 99.2 98.8 88.4 55.8 36.8 36.8

From Tables 8 to 14 and FIGS. 5 to 11, the deodorizing element using the functional mesh sheet of the present invention has excellent removability of malodorous components when it is repeatedly used. It turns out that it can be used over.

Example 2 Ultrafine Titanium Oxide (t) (Example of Functional Titanium Oxide (T))
Titanium oxide for photocatalyst "ST manufactured by Ishihara Sangyo Co., Ltd.
-01 "(Crystalline form: Anatase, Ti dried at 110 ° C)
O ₂ content: 95% by weight, X-ray particle size: 7 nm, BET specific surface area: 320 m ² / g) 30 parts, sepiolite as an inorganic filler (F) 7 parts and activated carbon having a particle size of 10 and several μm, 20 parts, organic fiber Using 20 parts of pulp as the quality material (P), 8 parts of ceramic fibers as reinforcing fibers, 5 parts of alumina sol as binder, 6 parts of latex emulsion and 4 parts of organic fibrous binder, wet papermaking was carried out according to a conventional method. As a result, a titanium oxide-containing paper having a basis weight of 170 g / m ² , a thickness of 0.28 mm, a density of 0.61 g / cm ³ , and a tensile strength of 2.8 kg / 15 mm was obtained. When this paper (base sheet (1a)) was exposed to the fire of a lighter, it was non-combustible, did not cause charring, and simply decreased in thickness.

A functional mesh sheet (1) was prepared from this base sheet (1a) in the same manner as in Example 1 to form a deodorizing element (3), and then a household air cleaner was improved. The deodorizing element (3) and the ultraviolet lamp (4) were incorporated to form a deodorizing device. The deodorizing effect when this was actually used was similar to that in Example 1.

Examples 3 to 6 As the inorganic filler (F), 25 parts of sepiolite (Example 3), 20 parts of bentonite (Example 4), 10 parts of magnesium sulfate and 10 parts of sepiolite (Example 5), 4 of sepiolite Example 1 was repeated except that 16 parts and 16 parts of asbestos (Example 6) were used to obtain a functional mesh sheet (1), and a deodorizing element (3) was prepared. In these cases also, a good deodorizing effect was obtained.

Examples 7 to 9 As modified ultrafine titanium oxide (t ') (an example of functional titanium oxide (T)), titanium oxide "ST-31" for photocatalyst manufactured by Ishihara Sangyo Co., Ltd. (crystal form: anatase, TiO ₂ content of the dried product at 110 ° C .: 81% by weight, ZnO content: 14% by weight, X-ray particle size: 7 nm, BET specific surface area: 260 m ² / g) 3
0 part, 5 parts of sepiolite as an inorganic filler (F), 20 parts of activated carbon having a particle size of 10 and several μm, 10 parts of alumina sol as a binder, 30 parts of latex emulsion and 5 parts of organic fibrous binder were added to 300 parts of water. Mixing was performed to prepare a coating liquid having a solid content concentration of 25% by weight.

Kraft paper having a basis weight of 75 g / m ² (Example 7), a laminated film of polyester / polyethylene having a thickness of 100 μm (Example 8), and a polyethylene-coated aluminum foil (Example 9) were coated with this coating solution. After that, it was dried to form a coating layer having a thickness of about 5 μm.

Using this as a base sheet (1a), a functional mesh sheet (1) was prepared in the same manner as in Example 1 to form a deodorizing element (3), and then a household air cleaner was improved. This deodorizing element (3) and UV lamp
(4) was incorporated to form a deodorizing device. The deodorizing effect when this was actually used was similar to that in Example 1.

[0074]

The functional titanium oxide (T) (fine titanium oxide (t) or modified ultrafine titanium oxide (t '), especially the latter) carried on the substrate sheet (1a) is excellent under the irradiation of light. It has the property of exerting an oxidative effect and promptly decomposing odors and organic substances that come into contact with it. At this time, the deodorizing effect is remarkable, and the malodorous components such as hydrogen sulfide and ammonia, which are difficult to be removed by a normal adsorption type deodorant, can be effectively removed.

In the deodorizing element and the deodorizing device using the functional mesh sheet of the present invention, ultraviolet rays reach the entire surface of the element, and therefore a good deodorizing ability is exhibited. Moreover, it is possible to prevent light leakage. In addition, this deodorizing element has the advantages that it is small in bulk, pressure loss is small, and the manufacturing cost can be minimized.

[Brief description of the drawings]

FIG. 1 is a plan view showing an example of a functional mesh sheet of the present invention.

FIG. 2 is a perspective view of a deodorizing element having a functional mesh sheet fixed in a widened state.

3 is a cross-sectional partial cutaway view of the deodorizing element of FIG. 2 in the transverse direction.

FIG. 4 is a schematic view of a deodorizing device incorporating the deodorizing element of FIG.

FIG. 5 is a graph showing the removal rate of ammonia in a repeated test.

FIG. 6 is a graph showing the acetaldehyde removal rate in a repeated test.

FIG. 7 is a graph showing acetic acid removal rates in repeated tests.

FIG. 8 is a graph showing the removal rate of trimethylamine in a repeated test.

FIG. 9 is a graph showing the removal rate of methyl mercaptan in repeated tests.

FIG. 10 is a graph showing a hydrogen sulfide removal rate in a repeated test.

FIG. 11 is a graph showing a styrene removal rate in a repeated test.

[Explanation of symbols]

(1) ... mesh sheet, (1a) ... base material sheet, (1b) ... intermittent slit, (2) ... frame, (3) ... deodorizing element, (4) ...
UV lamp

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI Technical display area B01J 35/02 B01D 53/36 ZABH

Claims (9)

[Claims] 1. A number of intermittent slits (1b) on a base sheet (1a).
A mesh sheet (1) capable of widening, wherein the base material sheet (1a) comprises an ultrafine titanium oxide (t) having an X-ray particle size of 100 nm or less or an ultrafine titanium oxide (t) thereof. Modified ultrafine titanium oxide whose surface is modified with metal or metal compound
A functional mesh sheet carrying a functional titanium oxide (T) composed of (t '). 2. A mesh sheet (1) capable of widening, wherein a large number of interrupt slits (1b) are arranged in parallel on a base material sheet (1a), and the slit positions of adjacent interrupt slits (1b) are displaced from each other. The functional mesh sheet according to claim 1, which has a provided shape. 3. The functional mesh sheet according to claim 1, wherein the base sheet (1a) is a single-layer or multi-layer sheet made of at least one of paper, nonwoven fabric, resin layer or metal foil. 4. A base material sheet (1a) carrying functional titanium oxide (T), comprising a functional titanium oxide (T) and an inorganic filler for carrying the functional titanium oxide (T). 2. The functional mesh sheet according to claim 1, which comprises a papermaking product containing F) and an organic fibrous material (P) having a papermaking ability as essential constituent components. 5. A functional titanium oxide (T) occupying the entire papermaking material.
And the total amount of the inorganic filler (F) are 5 to 90% by weight, the weight ratio of the functional titanium oxide (T) to the inorganic filler (F) is 0.02 to 20, and the organic fibrous material (P The functional mesh sheet according to claim 4, wherein the ratio of 5) is 5 to 90% by weight. 6. The inorganic filler (F) according to claim 4, wherein the inorganic filler (F) is at least one inorganic filler selected from the group consisting of sepiolite, silica gel, bentonite, zeolite, magnesium sulfate, asbestos and activated carbon. Functional mesh sheet. 7. The modified ultrafine titanium oxide (t ′) in which the weight ratio of the ultrafine titanium oxide (t) to the modifier metal or metal compound is 65:35 to 99: 1. The described functional mesh sheet. 8. A deodorizing element having the functional mesh sheet according to claim 1 fixed in a widened state. 9. A deodorizing device incorporating the deodorizing element according to claim 8 and an ultraviolet lamp.