JP6049175B2 - Interior using deodorant functional fabric and deodorant functional fabric - Google Patents

Description

  INDUSTRIAL APPLICABILITY The present invention is capable of deodorizing odors containing various chemical components such as aldehydes and acid gases, and has an interior that uses a deodorant functional fabric that has very little odor re-release, and the interior The present invention relates to a deodorant functional fabric used in the present invention.

In response to the improvement in indoor airtightness and the increase in cleanliness with the development of construction and mechanical technology, it is desired to remove unpleasant odors from the air in the living space. A blended fabric or the like is used.
The odor to be removed is composed of a wide variety of chemical substances, and deodorizers for each odor have been proposed, but it is considered that not all odors can be removed with one kind of deodorant. For this reason, deodorizing by using two or more types of deodorizers for odors in which various chemical components are mixed has been studied.

  For example, what is considered a bad odor includes aldehydes such as acetaldehyde, which is a component of tobacco odor, acidic gas derived from pets, alkaline gas, volatile organic compounds (VOC) derived from resin products, etc. All of these cannot be deodorized with a single deodorant. However, it has been known that when a plurality of deodorants are inadvertently blended in anticipation of a wide range of deodorizing functions, the deodorants cancel each other out and cannot perform their original functions.

In order to deal with this problem, for example, in Patent Document 1, in a fabric in which three types of carbon, a metal compound, and an amine compound are attached as a deodorant component, the carbon and the amine compound are not in direct contact with each other. Disclosure. Specifically, a mode in which different deodorant components are applied to the front side and the back side of the fabric, or one deodorant component supported on an inert porous carrier and the other deodorant component In the invention, the deodorant components that are not compatible with each other are prevented from coming into direct contact with each other and the original function of each deodorant is exhibited.
However, this invention is applied when a deodorant cannot be applied to both the front and back sides of the fabric for practical or technical reasons, or when a deodorant that cannot be supported on a porous carrier is used. I could not.

  Patent Document 2 discloses a makeup in which at least two types of deodorants and the like are separated from each other in the same plane on the surface of the surface decorative material of the building interior member (the surface of paper or a resin member). A decorative material is disclosed in which a material and two types of deodorant coating films each independently form a deodorant layer and are laminated together. The object of the present invention is to avoid that the deodorizers cancel each other's functions. According to the present invention, the deodorizer is formed as a separate layer rather than using a mixture of multiple types of deodorants. Has been confirmed to improve the deodorizing effect on multiple odors. However, in this document, the requirements for the surface cosmetic material other than the deodorizing function are not examined, and the practical value and feasibility are unknown.

On the other hand, fabrics used as interior materials for houses and vehicles are required to have various performances in addition to the deodorizing function, and flame retardancy is particularly important. In general, in order to impart a flame retardant function to a fabric, a flame retardant is imparted to the fabric by post-processing. Post-processing is often performed.
However, in addition to the deodorant and the flame retardant, such a treatment agent includes components such as a resin component and a filler serving as a binder between the fabric and the drug component, and the more the drug component contained in the treatment agent, the more the treatment agent contains. It becomes difficult to increase the concentration of each component due to compatibility problems. In addition, the effects of the deodorizers as described above may be offset and the flame retardancy may be reduced. Furthermore, the increase in the amount of added filler makes the coating layer of the treatment agent brittle, resulting in poor durability.
In addition, it is preferable that the flame retardant is applied to the entire fabric without a gap, whereas the deodorant does not necessarily have to be applied to the entire surface. There were also unreasonable points in treating with liquid.

In Patent Document 3, a first deodorant layer made of a resin composition containing activated carbon and a second deodorant layer containing an amine compound (deodorant) are laminated on the surface of the fabric. An invention is disclosed in which a processed fabric, wherein the first deodorant layer includes a flame retardant, and the second deodorant layer is formed in a dot-like pattern.
According to the invention of Patent Document 3, by forming the deodorant in two layers, in addition to eliminating the problem about the compatibility of the drug components, there is no mutual inhibition of the function of the deodorant, It is disclosed that a product excellent in texture and antistatic effect can be obtained by forming the second deodorant layer into a dot-like pattern.
However, it is inevitable that the thickness of the deodorant layer is increased and the texture of the fabric is lowered due to the lamination of the deodorant layer, and the durability between the deodorant layer and the fabric is lowered, so that the durability is not sufficient. It was not always a practical method.
Furthermore, conventionally, it has been difficult for any deodorant fabric to prevent re-release of odors once absorbed, and the problem of preventing re-release of odors has not been studied.

JP 2008-13870 A JP 2000-37819 A JP 2008-105370 A

  Therefore, the present invention uses a fabric to which a plurality of deodorants are added, and can be highly deodorized with respect to odors containing various components, and has an excellent texture and durability, and is used for the interior. An object is to provide a deodorant functional fabric.

  In the present invention, when a plurality of deodorants are used, not all are mixed together, but are contained in separate deodorant layers, and the fabric is provided without laminating those deodorant layers. The above-mentioned problems have been solved by using

That is, the present invention provides a vehicle interior using a fabric provided with a plurality of deodorants, wherein the first deodorant layer containing the flame retardant and the first deodorant is formed on the back surface. of the fabric portion, possess a second fabric portion where the second deodorant layer containing a flame retardant and a second deodorant is formed on the back surface, said first fabric portion and the second The present invention relates to an interior characterized in that the fabric portions are formed on different fabrics .
Since the interior of the present invention has a first fabric portion and a second fabric portion containing different deodorizers, it can deodorize various odors that cannot be handled with only one type of deodorant. Is possible. Further, since the interior of the present invention is formed so that the first deodorant layer and the second deodorant layer do not overlap, any deodorant layer is in contact with air and efficiently deodorized. It is possible to exert the effect, and since the function can be exhibited without canceling each other's effects, the deodorization efficiency is high. Furthermore, the re-release of the odor once deodorized is extremely small, and it is possible to maintain a comfortable environment for a long time after deodorization.
In addition, since the interior of the present invention does not have a deodorant layer, the thickness of the deodorant layer is thin and a fabric having a good texture can be obtained, and the adhesion between the deodorant layer and the fabric is good. Excellent durability. Furthermore, since the flame retardant is blended in both the first deodorant layer and the second deodorant layer, sufficient flame retardancy can be imparted to the fabric.
The interior of the present invention is also characterized in that a deodorant layer is formed on the back side of the fabric. The deodorizing function is exhibited by utilizing the breathability of the fabric, and the design and texture on the fabric surface side. The fabric's original design and texture can be maintained, and since the user does not come into direct contact with the deodorant layer, the deodorant layer can be prevented from being peeled off or deleted, and can be used for a long time. .

  The interior of the present invention is preferably an interior of a vehicle or a building. The interior and interior of a vehicle or building is a space where odors derived from various users such as people and pets and the environment are mixed, and the air tends to stagnate. Since a fabric provided with various types of deodorant layers is used, various odors can be efficiently reduced.

  In particular, it is preferable that the fabric to which a plurality of deodorants are applied is a vehicle interior skin material. The vehicle compartment is a relatively narrow space where odors are likely to stay, and in particular, since the seat is a portion in direct contact with a user or a pet, a plurality of deodorants are effectively arranged. A configuration is preferably used.

  In the interior of the present invention, the first deodorant layer and the second deodorant layer may be formed on different fabrics. When the first deodorant layer and the second deodorant layer are formed on different fabrics, different deodorant layers are used as members of various types of interior materials used in buildings and vehicles. Various odors can be deodorized as a whole space by appropriately selecting and using a plurality of fabrics. In addition, it is possible to arrange a fabric having an appropriate deodorant at an appropriate location in response to the uneven distribution of odors, and it is possible to effectively deodorize and to reduce the amount of deodorant used as a whole. Cost reduction

  In the fabric of the present invention, it is also preferable that the first fabric portion and the second fabric portion are formed in one continuous fabric. Since one fabric has both the first deodorant layer and the second deodorant layer, comprehensive deodorization corresponding to various odors can be performed using one fabric. Moreover, since a flame retardant is contained in both deodorant layers, a flame retardant will be provided over both deodorant layers, and the fabric excellent in the flame retardant effect can be obtained.

  The first deodorant and the second deodorant are preferably an amine compound and an inorganic metal salt. Amine compounds are mainly deodorant components with a high deodorizing effect on aldehyde-based odors, and inorganic metal salts are mainly deodorant components with a high deodorizing effect on acid and alkaline gases. is there. These deodorants have low compatibility, and when they are used in combination, their effects may be suppressed and the original functions may not be exhibited. However, as in the present invention, the fabric is formed as separate layers. By adding these deodorant components, compatibility problems can be solved.

In the interior of the present invention, it is more preferable that the first and / or second fabric portion has a reduction rate of acetaldehyde and / or acetic acid of 96% to 100% and a re-release of 0 to 5 ppm, More preferably, the reduction rate of acetaldehyde and / or acetic acid is 97% to 100% and the re-release is 0 to 2 ppm. It should be noted that both the reduction rate and the re-release are calculated according to the method described in Examples described later.
The reduction rate and re-release in such a numerical range means that it has an extremely high deodorizing effect and re-release preventing effect against aldehyde odor and / or acid gas odor, and is extremely useful in practical use. Highly deodorant interior.

In the interior of the present invention, the first fabric portion and the second fabric portion both have a burning rate of 0 mm / min to 100 mm / min, a bending resistance of 10 mm to 120 mm, and a constant load elongation of 1% to 180. % Is preferred. The combustion rate is calculated according to the formula described in the examples below. However, if the combustion does not proceed at all, or if the combustion is extremely slow and difficult to measure, the combustion rate is regarded as 0 or a very small value. It is. In addition, the constant load elongation rate is calculated according to the formula described in the examples below, but the elongation rate equivalent to that of an untreated fabric (a fabric not provided with a composition containing a deodorant), for example, an untreated fabric. If it is 80% of constant load elongation, it is more preferable. Further, the bending resistance is calculated according to the formula described in the examples described later, and is more preferably 10 mm to 100 mm.
A fabric having such a numerical range becomes a deodorant interior having a practically extremely high value in use, which has both the above-mentioned high deodorization functionality and sufficient flame retardancy and texture as an interior material.

  In the present invention, the first deodorant layer containing the flame retardant and the first deodorant and the second deodorant layer containing the flame retardant and the second deodorant are continuous. The present invention relates to a deodorizing functional fabric characterized in that it is formed in a continuous pattern substantially free of gaps on the back surface of the fabric. Such a fabric is suitably used as a space interior member, for example, a sheet skin member and / or a wallpaper fabric. According to the fabric of the present invention, since different types of deodorant layers are formed on one fabric, various odors can be effectively deodorized with one fabric. Moreover, the flame retardant is contained in any layer, and since these layers are formed substantially without gaps, the flame retardant is applied to the front surface of the fabric, and the flame retardant effect is also excellent. Furthermore, since the first deodorant layer and the second deodorant layer are formed in a continuous pattern, uneven distribution of the fabric's bending resistance, flame retardancy, etc. is eliminated, and the performance is stable. A deodorant functional fabric is obtained.

  The deodorant functional fabric preferably has a reduction rate of acetaldehyde and / or acetic acid of 96% to 100% and a re-release of 0 to 5 ppm. Further, it is more preferable that the reduction rate of acetaldehyde and / or acetic acid is 97% to 100% and the re-release is 0 to 2 ppm. The reduction rate and re-release in such a numerical range means that it has an extremely high deodorizing effect and re-release preventing effect against aldehyde odor and / or acid gas odor, and is extremely useful in practical use. High deodorant functional fabric.

  The deodorant functional fabric preferably has a burning rate of 0 mm / min to 100 mm / min, a bending resistance of 10 mm to 120 mm, and a constant load elongation of 1% to 180%. A fabric having such a numerical range becomes a deodorant interior having a practically extremely high value in use, which has both the above-mentioned high deodorization functionality and sufficient flame retardancy and texture as an interior material.

  According to the present invention, air mixed with various odors can be effectively deodorized, the odor once deodorized is extremely little released, and an interior having excellent fabric texture and durability can be realized. . Moreover, the deodorizing functional fabric used for this interior can be efficiently produced regardless of a special apparatus.

The interior of the present invention has a plurality of fabric portions on which layers containing different deodorants are formed, at least a first fabric portion and a second fabric portion. Each of these fabric parts is formed with a first deodorant layer and a second deodorant layer, and these deodorant layers are basically the same except for the deodorant component. It can be a composition.
Components other than the deodorant component in the deodorant layer include a flame retardant, a binder component, and the like.

Examples of flame retardants include bromine compounds used in vehicle seats, mixtures thereof with antimony, phosphoric acid compounds (for example, phosphoric acid ester compounds, condensed phosphoric acid ester compounds, phosphoric acid amide compounds, melamine phosphates) Compounds), metal hydroxide compounds, and the like. When using a commercially available flame retardant, for example, ammonium polyphosphate can be used.
The flame retardant contained in the first deodorant layer and the flame retardant contained in the second deodorant layer may be the same as or different from each other, and are selected according to the fabric on which the deodorant layer is formed. You can also

  As the binder component, a binder usually used as a fiber processing binder, for example, an acrylic resin or a urethane resin can be used.

  As other components, for example, hydroxyethyl cellulose or carboxymethyl cellulose can be used as a thickener.

The deodorant component is particularly effective for aldehyde-based odors such as acetaldehyde, formaldehyde, propanal, butanal, and acidic gas-based odors such as acetic acid, propionic acid, and n-butyric acid. An effective deodorant for isovaleric acid and the like can be used as the first and second deodorants.
Examples of the deodorant effective for the aldehyde-based odor include amine compounds. For example, adipic acid dihydrazide and a deodorant composition containing the same can be used.
Examples of the deodorant effective for acid gas-based odors include metal compounds. For example, zinc oxide and a deodorant composition containing the same can be used.

The first and second deodorant layers can be formed by applying a composition containing the above components to a fabric. The deodorant layer on the fabric can be formed to have a dry weight of about 60 to 160 g / m ² , preferably about 80 to 130 g / m ² . Each component in the deodorant layer can be, for example, a binder component of 25-35%, a flame retardant of 45-55%, and a deodorant component of 14-20%.

As a fabric forming the deodorant layer, a fabric generally used for interiors of vehicles and homes can be used. For example, there are woven fabrics, knitted fabrics, non-woven fabrics, brushed fabrics, flocked fabrics, etc. with a basis weight of 100-1500 g / m ² , and the materials may be polyester, polypropylene, polyurethane, acrylic, etc. synthetic fiber fabrics, wool Natural fiber fabrics such as cotton may be used, and fabrics in which these are blended and woven may be used. For example, in the case of a vehicle seat skin material, polyester is preferably used.

The fabric having the deodorant layer of the present invention preferably has a deodorant layer formed on the back surface thereof. The back surface means a surface that is exposed on the surface of a vehicle or a building and is not visually recognized by the user. By having a deodorant layer on the back side, the texture and aesthetics on the fabric surface side are not spoiled, and the deodorant layer can be prevented from falling off or deteriorating due to contact with the user. Even when the layer is opaque or colored gray or black, it can be used without any problem.
As a method for imparting a deodorant layer to the fabric, a known method can be appropriately selected and used. For example, coating with a knife coater, blade coater, bar coater, etc., rotary screen printing, flat screen printing, Examples thereof include a printing method such as roller printing.

The interior of the present invention has a first fabric portion having a first deodorant layer and a second fabric portion having a second deodorant layer, but these fabric portions are different fabrics. Even if formed, it may be formed on the same fabric.
When the first fabric portion and the second fabric portion are formed on different fabrics, the fabric having the first fabric portion and the fabric having the second fabric portion are separately created by a known creation method. And they can be used in combination in the interior of vehicles and buildings. For example, in the case of an automobile, the front seat and the rear seat in the passenger compartment may be made of different types of fabrics, and the upper and lower portions of the seat may be made of different types of fabrics. The skin material and the skin material of the ceiling part or floor part may be formed of different types of fabrics.

  The fabrics having different types of deodorizers can be appropriately arranged according to the place where the odor is generated or the staying place. For example, since aldehyde-based odors are generally derived from tobacco and the like, a fabric having a deodorant effective for aldehyde-based odors is placed near the front sheet, and acid gas-based odors are Since it is often derived from pets and the like, there is a configuration in which a fabric having a deodorant effective for acid gas-based odors is arranged in the vicinity of the rear sheet where pets are often placed. Further, for example, in order to deal with an odor heavier than air, a fabric having a deodorizing agent may be disposed on the floor portion or the seat seat surface portion, and the interior of the other portion may be configured with a normal fabric. Tobacco smoke and volatile gases tend to stay, and it is also possible to exert a deodorizing function effectively by placing a deodorizing fabric on the ceiling, which is a relatively large interior area. is there. Thus, by arranging different types of fabrics according to the type of odor, the deodorant can be efficiently arranged, the amount of the deodorant used can be reduced, and the cost is advantageous.

  On the other hand, when the first fabric portion and the second fabric portion are formed on the same fabric, the first fabric is formed on the back surface of one fabric by a known production method such as rotary screen printing. The portion and the second fabric portion are formed separately, and the fabric can be used in the interior of a vehicle or a building. The form in the case of forming a plurality of fabric portions on the fabric is not particularly limited. Specifically, the pattern is continuous, such as a checkered pattern, a polygon (triangle, quadrilateral, hexagonal shape, etc.), a continuous curve diagram shape, etc. It can be set as the form coated with substantially no gap. The size of the continuous pattern is preferably set to a certain level or less in order to ensure the flame retardance performance and the texture uniformity of the entire fabric. If such a fabric is used, it is possible to efficiently deodorize many types of odors with one type of fabric, and the types of members constituting the interior can be reduced.

  In the interior or deodorant functional fabric of the present invention, the type of the deodorant layer is typically two, but may be three or more. Even in the case of three or more types, as in the case of the two types, the fabric portions having the respective deodorant layers may be formed on separate fabrics, or may be formed on the same fabric. . Further, for example, two types may be formed on the same fabric and further used in combination with a fabric having another deodorant layer.

  Next, although an Example is shown about the combination of the fabric which concerns on this invention, this invention is not limited by these Examples.

[material]
1. Fabric: In all Examples and Comparative Examples, a polyester fabric (weight per unit area: 400 g / m ² ) used as an interior material was used.
2. Deodorant: Commercial deodorants a to i shown in the following table were used. Deodorants a, b, c and d are deodorizers containing inorganic metal salts, and deodorants e, h and i are deodorizers containing amine compounds.

[Creation of test fabric]
1. Treatment by Back Coating (BC) A predetermined amount of the coating composition shown in the table below is applied to a polyester fabric (400 g / m ² per unit area) with a knife coater, and dried at 150 ° C. for 3 minutes. Got.

2. Treatment with DipNip A polyester fabric (400 g / m ² basis weight) was applied with a composition containing each deodorant by the DipNip method to obtain a fabric for use in Examples and Comparative Examples. The composition given to the fabric is as shown in the table below.

測定後、新たなテドラーバッグに生地を入れ替え、Ｎ_２ガスを封入して初期ガス濃度を測定し、６５℃で一定時間静置した後、再度ガス濃度を測定し、下記式によって再放出された臭気濃度を算出した。
［式２］

評価は○、×の２段階評価とし、評価基準は下表のとおりとした。 [Test method]
1. Deodorization test / re-release test The dough provided with each specified amount of deodorant is put in a tedlar bag, various test gases are enclosed, the initial gas concentration is measured, and after standing at 35 ° C. for a certain period of time, The gas concentration was measured again using a gas detector tube (manufactured by Gastec), and the odor reduction rate was calculated by the following formula.
[Formula 1]

After measurement, the dough is replaced with a new Tedlar bag, N ₂ gas is sealed, the initial gas concentration is measured, and after standing at 65 ° C. for a certain period of time, the gas concentration is measured again, and the odor re-released by the following formula Concentration was calculated.
[Formula 2]

The evaluation was a two-step evaluation of ○ and ×, and the evaluation criteria were as shown in the table below.

2. Combustion test About each fabric, the flame retardance performance was confirmed by the method based on US automobile safety standard FMVSS 302. The test piece was 350 mm long × 100 mm wide. The burning rate was calculated by the following formula. The evaluation was made in two stages, ○ and ×, and the evaluation criteria were as shown in the table below.
[Formula 3]

3. General physical property test About each test cloth, each item of bending resistance, resin drop-off, elongation performance, whitening, and presence / absence of wrinkles was confirmed, and evaluated in two stages of ○ and ×. The whitening and wrinkles were confirmed by visual observation, and the bending resistance, resin dropout, and elongation performance were determined by the following test methods.
(1) Bending softness test Bending softness was measured by the method based on JISL1096A method and 45 degree cantilever method. The test piece was 200 mm long × 25 mm wide. As the evaluation criteria, those having a moving distance of 100 mm or less were evaluated as ◯, and those exceeding 100 mm were evaluated as ×.
(2) Scratch resistance test (confirmation test for resin dropout)
The fir resistance was measured by a method based on JISK6404-6. The test piece was 100 mm long × 25 mm wide. As the evaluation criteria, the grade of each test piece was determined according to the following table, and grade 3 or higher was rated as “◯”, and grade 2 or lower was marked as “x”.

(3) Constant load elongation test (elongation performance confirmation test)
A test piece having a length of 300 mm and a width of 80 mm was used, and the test was performed in each of the vertical direction and the horizontal direction. The test piece was scored at 100 mm intervals in the center in the length direction, and one end of the test piece was held by the upper grip using a Martens fatigue tester, and the grip interval was 160 mm. A weight with a total mass of 10 kg including the gripping tool was attached to the lower part of the test piece, and the weight was suspended for 10 minutes. After leaving, the gauge interval (L) with the weight suspended was measured, and the constant load elongation (%) was calculated from the following equation. The test was repeated for three test pieces, and the average value was calculated. The evaluation criteria were ◯ for a constant load elongation of 5% or more and x for less than 5%.
[Formula 4]

[Example 1]
A fabric having a back coating layer containing the deodorant c and a fabric having a back coating layer containing the deodorant i were prepared in accordance with the above-described cloth back coating method. The amount of deodorant was 56 g / m ² . The deodorization test, the combustion test, and the general physical property test were performed in accordance with the method described above. The results are shown in Table 7.
[Example 2]
A fabric having a back coating layer containing a deodorant c and a fabric having a back coating layer containing a deodorant i, as in Example 1, except that the amount of the deodorant was 28 g / m ^2. And created. These were subjected to a deodorization test, a combustion test, and a general physical property test. The results are shown in Table 7.
[Example 3]
A fabric having a back coating layer containing the deodorant c and a fabric having a back coating layer containing the deodorant i in the same manner as in Example 1 except that the amount of the deodorant was 20 g / m ^2. And created. These were subjected to a deodorization test, a combustion test, and a general physical property test. The results are shown in Table 7.
[Example 4]
A fabric having a back coating layer containing deodorant c and a fabric having a back coating layer containing deodorant i, as in Example 1, except that the amount of deodorant was 14 g / m ^2. And created. These were subjected to a deodorization test, a combustion test, and a general physical property test. The results are shown in Table 7.

  As shown in Table 7, an implementation using a fabric having a composition layer containing deodorant c and a flame retardant and a fabric having a composition layer containing deodorant i and a flame retardant In Examples 1 to 4, the deodorization and re-release were both ◯ for both acetaldehyde and acetic acid, indicating extremely high deodorization performance. In addition, the results of the flammability and general physical property tests were all “good”. In other words, Examples 1 to 4 showed excellent results in all of deodorant properties, flame retardancy, and general physical properties.

[Example 5]
A fabric having a back coating layer containing the deodorant d and a fabric having a back coating layer containing the deodorant i are prepared in accordance with the above-described method for producing the fabric and used for the deodorization test and general physical property test. did. The amount of deodorant was 56 g / m ² . The results are shown in Table 8.
[Example 6]
A fabric having a back coating layer containing a deodorant d and a fabric having a back coating layer containing a deodorant i in the same manner as in Example 5 except that the amount of the deodorant was 28 g / m ^2. And created. These were subjected to a deodorization test and a general physical property test. The results are shown in Table 8.
[Example 7]
A fabric having a back coating layer containing a deodorant d and a fabric having a back coating layer containing a deodorant i in the same manner as in Example 5 except that the amount of the deodorant was 14 g / m ^2. And created. These were subjected to a deodorization test and a general physical property test. The results are shown in Table 8.

  As shown in Table 8, a fabric having a composition layer containing a deodorant d and a flame retardant and a fabric having a composition layer containing a deodorant i and a flame retardant were used together. Examples 5 to 7 showed high deodorizing performance with respect to both acetaldehyde and acetic acid. In other words, the deodorizing performance was all good for both acetaldehyde and acetic acid. Moreover, all the general physical properties were ○.

[Comparative Example 1] Example of fabric having a back coating layer containing a plurality of deodorants Using the composition containing deodorants a and i in Table 2, the deodorant a and A fabric having a back coating layer containing i was prepared. The amount of deodorant was 16 g / m ² . The deodorization test, the combustion test, and the general physical property test were performed in accordance with the method described above. The results are shown in Table 9.
[Comparative Example 2] Example of fabric having a layer containing a plurality of deodorants A composition containing deodorizers h and i in Table 2 was used, and deodorizers h and i were applied according to the back coating method described above. A fabric having a back coating layer was prepared. The amount of deodorant was 16 g / m ² . The deodorization test, the combustion test, and the general physical property test were performed in accordance with the method described above. The results are shown in Table 9.

As shown in Table 9, Comparative Example 1 using a fabric having a composition layer containing deodorants a and i and a flame retardant is ◯ or × for acetaldehyde, and acetic acid rerelease test X was not achieved.
In Comparative Example 2 using a fabric having a composition layer containing deodorizers h and i and a flame retardant, acetic acid re-release was x and performance was not achieved.

[Comparative Example 3] Example of fabric in which a plurality of deodorizers are applied in multiple layers After applying the deodorant b having the composition shown in Table 3 to the fabric by the DipNip method, the fabric has the composition shown in Table 2 Deodorant i was applied with a knife coater to prepare a fabric having a back coating layer containing deodorant i. The amount of deodorant was 18 g / m ² . The deodorization test, the combustion test, and the general physical property test were performed in accordance with the method described above. The results are shown in Table 10.
[Comparative Example 4] Example of fabric to which a plurality of deodorizers were applied multiple times The fabric was the same as in Comparative Example 3 except that the deodorizer applied by the DipNip method was changed to the deodorizer c having the composition shown in Table 3. Created. The amount of deodorant was 18 g / m ² . The deodorization test, the combustion test, and the general physical property test were performed in accordance with the method described above. The results are shown in Table 10.
[Comparative Example 5] Example of fabric to which a plurality of deodorants were applied in multiples The fabric was the same as in Comparative Example 3 except that the deodorizer applied by the DipNip method was changed to the deodorant d having the composition shown in Table 3. Created. The amount of deodorant was 20 g / m ² . The deodorization test, the combustion test, and the general physical property test were performed in accordance with the method described above. The results are shown in Table 10.
[Comparative Example 6] Example of fabric having multiple deodorants and multiple deodorants in one layer Deodorant e having the composition shown in Table 3 was applied to the fabric by the DipNip method. Thereafter, a composition containing deodorants a and i having the composition shown in Table 2 was applied to the cloth with a knife coater to prepare a fabric having a back coating layer containing deodorants a and i. The amount of deodorant was 23 g / m ² . The deodorization test, the combustion test, and the general physical property test were performed in accordance with the method described above. The results are shown in Table 10.
[Comparative Example 7] Example of Fabric Having Two Overlapping Back Coating Layers A composition containing a deodorant i having the composition shown in Table 2 was applied to a fabric with a knife coater to contain the deodorant i. A fabric having two layers of a back coating layer containing deodorant i and a back coating layer containing deodorant c by creating a back coating layer and further applying a composition containing deodorant c with a knife coater And prepared for deodorization test, combustion test and general physical property test. The amount of deodorant was 20 g / m ² . The results are shown in Table 10.

As shown in Table 10, Comparative Example 3 using a fabric in which each of the deodorizers b, c, and d was applied with DipNip and then back-coated with a layer of a composition containing the deodorizer i and the flame retardant. As for ˜5, the acetic acid re-release test was x, the flame retardancy was not achieved, and resin dropping was observed. In Comparative Example 3, flaking at the time of dipping was also observed.
In addition, Comparative Example 6 using a fabric in which a layer of a composition containing deodorizers a and i and a flame retardant was applied after applying the deodorizer e with DipNip, flame retardancy was not achieved, Whitening and wrinkle were observed during dipping.
Comparative Example 7 using a fabric that was back-coated so that the layer of the composition containing the deodorant i and the flame retardant and the layer of the composition containing the deodorant c and the flame retardant became two layers, The flame retardancy was not achieved, the elongation performance and the bending resistance were also poor, the resin was observed to fall off, and the general physical properties were poor.

Claims (6)

A vehicle interior using a fabric provided with a plurality of deodorants, a first fabric portion on which a first deodorant layer containing a flame retardant and a first deodorant is formed on the back surface; possess a second fabric portion flame retardant and the second deodorant layer containing a second deodorant is formed on the rear surface,
The interior characterized in that the first fabric portion and the second fabric portion are formed in different fabrics . In the passenger compartment, the skin material of the front seat and the skin material of the rear seat are made of the different fabrics, or the skin material of the upper portion of the seat and the skin material of the lower portion of the seat are made of the different fabrics. The interior according to claim 1, wherein the seat skin material and the ceiling skin material or the floor skin material are made of the different fabrics. The interior according to claim 1 or 2, wherein the first deodorant and the second deodorant are an amine compound and an inorganic metal salt, respectively . 4. The method according to claim 1, wherein the first fabric portion or the second fabric portion has an acetaldehyde reduction rate of 96% to 100% and a re-release of 0 to 5 ppm . The interior according to item 1. 5. The method according to claim 1, wherein the first fabric portion or the second fabric portion has an acetic acid reduction rate of 96% to 100% and a re-release of 0 to 5 ppm . The interior according to item 1. The first fabric portion or the second fabric portion has a burning rate of 0 mm / min to 100 mm / min, a bending resistance of 10 mm to 120 mm, and a constant load elongation of 1% to 180%. The interior according to any one of claims 1 to 5.