JP6342261B2 - Nanofiber coating sheet and inspection method for this coating sheet - Google Patents

Description

  The present invention relates to a coating sheet obtained by coating nanofibers on the surface of a base sheet, and an inspection method for inspecting the nanofiber coating state of the coating sheet.

  A coating sheet has been developed in which nanofibers are coated on the surface of a base sheet to realize excellent properties that cannot be realized with a single base sheet (see Patent Document 1). This coating sheet is used for a filter, for example, to realize excellent characteristics. This is because the nanofiber coating layer can remove fine particles that cannot be filtered by conventional filter paper. In this filter, nanofibers are attached to the surface of the filter paper, and a fine mesh filter that cannot be realized with a filter paper mesh is realized with nanofibers. Nanofibers are extremely thin compared to the fibers of filter paper, and fine nanofibers form a fine mesh filter on the surface of the filter paper. The fine mesh of the nanofiber deposits and removes very fine foreign substances contained in the air and liquid that permeate the surface, that is, filters the surface to deposit the foreign substances on the surface of the filter.

  In contrast, conventional filter paper that does not have nanofibers attached to the surface is removed by foreign matter entering the voids of the fiber, so that the removed foreign matter enters the filter and cannot be easily removed. There is a drawback that it is difficult to eliminate clogging. In contrast, a filter with nanofibers laminated on the surface removes clogging quickly by removing the foreign matter from the filter surface because the foreign matter is deposited on the surface and removed. There is.

  Although excellent characteristics are realized by coating nanofibers on the surface, it is extremely difficult to confirm whether or not nanofibers are normally coated on the surface of the base sheet in the manufacturing process. This is because the nanofibers are extremely thin and invisible, so it cannot be visually confirmed whether or not the surface of the base sheet is coated. Further, nanofibers thinner than the wavelength of visible light cannot be confirmed in coating state even when an optical microscope is used, and it is necessary to confirm the adhesion state using an electron microscope. Inspecting with an electron microscope requires much labor to inspect the coating state. This is because the coating sheet is placed in a vacuum chamber and evacuated for inspection. Furthermore, in addition to the time-consuming inspection, the method using an electron microscope cannot inspect the coating state on the entire sheet surface, and can only perform local inspection. This is because the inspection with the electron microscope cuts the coating sheet to prepare a sample for inspection and puts the sample in a vacuum chamber for inspection, so that only the portion cut as a sample is inspected.

JP 2014-124578 A

  The present invention has been developed for the purpose of solving the above drawbacks. An important object of the present invention is to provide a coating sheet that can easily inspect whether or not a nanofiber coating layer is attached to the surface of the coating sheet, and an inspection method thereof.

Means and effects for solving the problems

  The coating sheet according to claim 1 of the present invention is provided with a nanofiber coating layer 2 by attaching nanofibers to the surface of the base material sheet 1. The nanofiber of this coating sheet is a fluorescent molecule-containing nanofiber containing fluorescent molecules that emit light when excited.

  The above coating sheet has a feature that it can be easily inspected whether or not a nanofiber coating layer is attached to the surface of the coating sheet. This is because the coating of the nanofiber can be determined by detecting the emission of the fluorescent molecule by exciting the fluorescent molecule of the fluorescent molecule-containing nanofiber. In particular, the coating sheet described above detects the nanofiber coating by exciting the fluorescent molecules and detecting the fluorescence, so that the coating sheet looks like the conventional method of inspecting the surface of the coating sheet with an electron microscope. It is not necessary to inspect the sample by cutting it into a vacuum chamber, and whether the coating sheet surface emits fluorescence by irradiating the surface of the coating sheet with light that excites fluorescent molecules, etc. Can inspect nanofiber coatings. This is because the portion not coated with the fluorescent molecule-containing nanofibers does not emit fluorescence even when excited, and the portion coated with the fluorescent molecule-containing nanofibers detects fluorescence emitted.

In the coating sheet of the present invention, the nanofibers of the coating layer 2 are fluorescent molecule-containing nanofibers containing silica nanoparticles containing fluorescent molecules . This coating sheet has a feature that fluorescent molecule-containing nanofibers can be easily produced.

  The coating sheet of this invention can make the average particle diameter of a silica nanoparticle below 1/2 of the thickness of a fluorescent molecule containing nanofiber. This coating sheet can contain fluorescent molecules by reducing the strength reduction of the fluorescent molecule-containing nanofibers.

  The coating sheet of the present invention can be a pre-filtration layer in which the base sheet 1 is filter paper, the coating layer 2 is attached to the surface of the filter paper, and finer particles than the filter paper are filtered and removed. This coating sheet can remarkably improve the filtration characteristics of the filter paper by the coating layer. In particular, fine particles that cannot be filtered only with filter paper can be filtered with a coating layer.

  In the coating sheet of the present invention, the base sheet 1 can be a filter for filtering vehicle air or liquid. This coating sheet can filter out fine foreign substances contained in air, engine oil, fuel, etc., which are inhaled into the engine of the vehicle, so it is effective for engine wear, deterioration, failure, etc. due to fine foreign substances. Can be prevented.

  In the coating sheet of the present invention, the thickness of the fluorescent molecule-containing nanofiber can be 800 nm or less and can be 50 nm or more. This coating sheet is used for various applications by a fluorescent molecule-containing nanofiber having a specific thickness, and realizes excellent physical properties that cannot be realized by a base sheet alone.

  The inspection method of the present invention is a method for inspecting a coating sheet formed by laminating a coating layer 2 made of nanofibers on the surface of a base sheet 1, and includes fluorescent molecules that emit light when excited. It comprises a production process for producing a nanofiber and a light detection process for detecting the emission of the excited fluorescent molecule by exciting the fluorescent molecule of the nanofiber containing the fluorescent molecule, and from the nanofiber containing the fluorescent molecule in the light detection process. Is detected, and the coating layer 2 is detected.

  The coating sheet inspection method described above has a feature that it is possible to easily inspect whether or not the nanofiber coating layer is attached to the surface of the coating sheet. This is because the coating of the nanofiber can be detected from the emission of the fluorescent molecule by exciting the fluorescent molecule of the nanofiber containing the fluorescent molecule. In particular, the coating sheet inspection method described above detects the nanofiber coating by exciting the fluorescent molecules and detecting the fluorescence, so that the surface of the coating sheet is inspected with an electron microscope. It is not necessary to cut the coating sheet into a test piece and put it in a vacuum chamber for inspection, and the coating sheet surface emits fluorescence by irradiating the surface of the coating sheet with light that excites fluorescent molecules. Whether or not the nanofiber coating can be inspected. This is because the portion not coated with the fluorescent molecule-containing nanofibers does not emit fluorescence even when excited, and the portion coated with the fluorescent molecule-containing nanofibers detects fluorescence emitted.

In the method for inspecting a coating sheet of the present invention, fluorescent molecules are added to silica nanoparticles and added to nanofibers in the production process .

It is sectional drawing of the coating sheet concerning the Example of this invention. It is an electron micrograph of the coating sheet shown in FIG. It is a graph which shows the fluorescence intensity with respect to the application quantity of nanofiber. It is a side view which shows the inspection method of the coating layer of the coating sheet surface. It is a figure which shows a light emission density | concentration difference by exciting a coating sheet.

  Embodiments of the present invention will be described below with reference to the drawings. However, the examples shown below exemplify the coating sheet and its inspection method for embodying the technical idea of the present invention, and the present invention does not specify the coating sheet and its inspection method below.

  Further, in this specification, in order to facilitate understanding of the scope of claims, numbers corresponding to the members shown in the examples are indicated in the “claims” and “means for solving problems” sections. It is added to the members. However, the members shown in the claims are not limited to the members in the embodiments.

  The coating sheet shown in the cross-sectional view of FIG. 1 is provided with a coating layer 2 made of nanofibers by attaching nanofibers to the surface of a substrate sheet 1. FIG. 2 shows an electron micrograph of the coating sheet as seen from the surface. In this figure, fibers thicker than 1 cm indicate fibers of the base sheet 1, and thin white fibers of 1 mm or less indicate nanofibers. As shown in this figure, the coating sheet has nanofibers attached to the surface of the base material sheet 1 without directivity, and a finer mesh than the fibers of the base material sheet 1 is provided by the nanofibers.

  The coating sheet of FIG. 2 is a filter in which nanofibers are attached to the surface of a filter paper and the coating layer 2 is provided on the surface. The coating sheet used for the filter uses the base sheet 1 as filter paper or nonwoven fabric. A filter made of a coating sheet can filter fine particles that cannot be filtered by filter paper or nonwoven fabric. The filter of a coating sheet is used for the filter which filters the air or liquid for vehicles, and can improve a filtration characteristic remarkably. This is because the coating layer 2 removes fine particles by filtration. The coating sheet filter is used as a filter for air taken into the engine of a vehicle, or as a filter for engine oil, power steering oil, etc., used for oil for automatic transmission, and also used as a fuel filter. Then, fine foreign matters contained in air, oil and fuel are filtered and removed.

  The filter of the coating sheet used for air removes fine particles from the air sucked into the engine to make it clear air, so the damage of the sliding part between the cylinder and piston is reduced, and the engine Prevent wear and deterioration of Also, the coating sheet filter used for engine oil keeps the engine oil clean and prevents wear and deterioration of the sliding part between the cylinder and piston, effectively preventing damage and failure due to wear. . The filter of the coating sheet used for the oil for automatic transmission removes fine foreign matters to prevent the automatic transmission from malfunctioning or shifting errors due to the foreign matters, and the filter used for fuel is included in the fuel. Even fine particles are removed, and an extremely clear fuel is supplied to the engine. Therefore, the operations of the fuel pump and the fuel injection valve are accurately controlled, and an accurate amount of fuel can be supplied into the cylinder. In particular, even in a diesel engine having a high injection pressure, the operation of the fuel injection valve is accurately controlled, the fuel injection amount and the injection timing are accurately controlled, and the engine can be operated in an ideal state. In addition, a feature that can effectively prevent wear, damage, and failure of the fuel pump and the fuel injection valve due to foreign matters contained in the fuel is realized.

  The nanofiber of the coating layer 2 is a nanofiber containing a fluorescent molecule. A rhodamine dye that emits light when excited by light is suitable for the fluorescent molecule contained in the nanofiber. The rhodamine dye is excited by 555 nm light and emits 590 nm light. However, the present invention does not limit the fluorescent molecule to a rhodamine dye, and other fluorescent molecules that emit light at a wavelength different from that of the excitation light, such as all fluorescent molecules that can be added to the nanofiber, such as fluorescein isocyanate and sulfollowodamine. Etc. can also be used. Fluorescein isocyanate is excited with 490 nm light and emits 525 nm light, and sulfoerdamine is excited with 575 nm light and emits 590 nm light. Fluorescent molecules that can be used include those that emit light when excited by electromagnetic waves such as ultraviolet rays instead of visible light, and those that emit light when excited by an energy beam such as an electron beam.

The nanofiber of the coating layer 2 is made into a fluorescent molecule-containing nanofiber by adding silica nanoparticles containing a fluorescent molecule in a process of processing into a fiber .

  The fluorescent molecule-containing nanofibers containing silica nanoparticles have an average particle diameter of silica nanoparticles set to ½ or less of the thickness of the fluorescent molecule-containing nanofibers, and prevent strength reduction due to the contained silica nanoparticles. The thickness of the fluorescent molecule-containing nanofiber is not specified, but is preferably 800 nm or less and 50 nm or more, more preferably 500 nm or less and 100 nm or more.

  Silica nanoparticles containing fluorescent molecules can be produced by the following steps.

[Stover method]
After 11.7 mg of Sulforhodamine B (Kanto Chemical Co., Ltd.) is dissolved in 4 ml of ethanol, 0.1 ml of tetraethylorthosilicate (TEOS) (Wako Pure Chemical Mining Co., Ltd.) is added and mixed. Then, while adding 1 ml of distilled water and magnetically stirring at room temperature, 0.1 ml of concentrated aqueous ammonia is added and stirred at room temperature for about 3 days. (At this stage, TEOS hydrolysis and polycondensation occur, and SiO ₂ begins to form. At this time, sulfurhodamine B molecules are mixed and fixed in the silica nanoparticles. Concentrated aqueous ammonia acts as a catalyst for this reaction. Then, using an ultrafiltration device (Millipore stirring type cell) with ethanol as a dispersion medium, the filtrate is washed until it is not colored. At that time, a sample of 10 nm or less was taken out as a filtrate with an ultrafiltration apparatus in which a YM-100 filter (pore size: about 10 nm) was set, and the dispersion was used as an ultrafiltration device in which a YM-10 filter (pore size: about 2.6 nm) was set. The filtrate is divided into a filtrate containing a sample of 2.6 nm or less and a dispersion liquid (within an ultrafiltration device) containing a sample of 2.6 nm to 10 nm. Finally, 5 ml of a silica nanoparticle ethanol dispersion having 2.6 nm <D <10 nm of Sulforhodamine B immobilized (containing 0.72% by weight of silica nanoparticles) was obtained.

Examples of a method for incorporating fluorescent molecules into silica nanoparticles in the Stover method include (1) and (2).
(1) Mixing method Fluorescent molecules are dissolved in a solution before TEOS polycondensation, so that they are naturally incorporated when silica nanoparticles are formed.

(2) Silica Coupling Method In order to ensure the uptake of the fluorescent molecule, it is combined with the silane coupling reagent and Si—O— is introduced into the fluorescent molecule so that it is combined and incorporated during the TEOS polycondensation.

Silica nanoparticles containing a rhodamine dye can be prepared by the above method, but silica nanoparticles can also be produced by a core-shell method or a silica nanoparticle core surface modification method.
In the core-shell method, the surface of a metal particle with a radius of about 15 nm is adsorbed on the side chain of a fluorescent particle (S- or -N-) (within the surface area of the metal particle core), and amino orthosilicate (APS) is further absorbed into the metal particle core. In order to carry out polycondensation of silicate at the silicate group (—Si—O—) of the APS adsorbed on the surface of the metal particle core, water glass (NaSi _x O _2-x ) is added and several Let react for a day. Thereafter, when the metal fine particle core is dissolved with NaCN to form a silica capsule, fluorescent molecules remain inside. Distilled water washing is performed several times by ultrafiltration, and NaCN and NaAu (CN) ₂ are removed to obtain silica nanoparticles.

  The produced fluorescent molecule-containing silica nanoparticles can be adjusted in particle size according to the concentration of reagent added during adjustment, the concentration of aqueous ammonia, the reaction time, and the temperature. Furthermore, by the ultrafiltration method, the pore size of the filter to be used can be selected to set the particle size to a specific range. In this method, a particle size having a size of 2.6 nm <size <10 nm or 0.6 nm <size <2.5 nm can be extracted by combining filters to be used.

The coating sheet detects whether the nanofibers are normally applied by detecting the emission of fluorescent molecules. Therefore, the fluorescent molecule-containing nanofiber is added with a content of fluorescent molecules capable of detecting luminescence. Dispersion of silica nanoparticles with rhodamine dye: 11.5 wt., Polymer concentration: 8 wt. Can detect luminescence with a coating amount of 0.04 g / m ² or more on the surface of the substrate sheet 1.

The fluorescent molecule-containing nanofiber can be produced by the following method. However, the fluorescent molecule-containing nanofibers are not specified as follows.
Example 1
As Example 1 of the present invention, fluorescent molecule-containing nanofibers are applied as a coating layer 2 to the surface of the base sheet 1 by the following manufacturing method.
1) Preparation step First, 80.50 g of DMF is put into a 200 ml beaker, and 8.00 g of PVDF (polyvinylidene difluoride) is put into the beaker and completely dissolved to obtain a 9.04 wt% PVDF / DMF solution.
Next, a rhodamine dye-containing silica nanoparticle / ethanol dispersion is added at a rate of 1.15 g to 8.85 g of the PVDF / DMF solution obtained above to obtain a coating solution.
2) Spinning step Next, the coating solution produced in the above adjustment step is coated with fluorescent molecule-containing nanofibers as a coating layer 2 on the base sheet 1 using an electrospinning device to obtain a coating sheet. Here, 110 g / m ² of filter paper is set as the base material sheet 1 on the surface of the rotating drum collector, and fluorescent molecule-containing nanofibers are applied as a coating layer on the filter paper to obtain a coating sheet. In addition, a stainless steel nozzle having an inner diameter of 0.40 mm and a length of 19 mm is used as the metal nozzle, the distance from the lower end of the metal nozzle to the surface of the base sheet 1 is 20 cm, and the movement distance of the metal nozzle is 20 cm. The speed was 5 mm / sec, the drum collector was rotated at 50 rpm, the applied voltage was 21 kV, the discharge speed of the coating solution was 0.2 ml / hr, applied at a temperature of 23 degrees and a humidity of 15% for 22.5 minutes. A coating sheet having 045 g / m ² of the fluorescent molecule-containing nanofiber nonwoven fabric is obtained.

(Example 2)
A coating sheet having a fluorescent molecule-containing nanofiber nonwoven fabric of 0.090 g / m ² as the coating layer 2 was obtained in the same manner as in Example 1 except that the spinning time was 45.0 minutes.

(Example 3)
A coated sheet having a fluorescent molecule-containing nanofiber nonwoven fabric of 0.135 g / m ² as the coating layer 2 was obtained in the same manner as in Example 1 except that the spinning time was 67.5 minutes.

The fluorescent molecule-containing nanofibers obtained in the above steps are applied to the surface of the substrate sheet 1 to provide the coating layer 2. The coating amount of the fluorescent molecule-containing nanofiber is adjusted to an optimum amount for the application. The coating amount of the fluorescent molecule-containing nanofibers is adjusted so that the filter coating sheet removes fine foreign matter with the coating layer 2 on the surface of the base sheet 1 and allows the coating layer 2 to pass through a gas or liquid. Is done. The emission intensity of the coating sheet coated with the fluorescent molecule-containing nanofiber is shown in FIG. The coating sheet shown in this figure can detect luminescence when the attached amount of the nanofibers containing fluorescent molecules is 0.04 g / m ² or more, can detect luminescence more strongly when the coating amount is 0.08 g / m ² or more, The emission intensity detected at 0.135 g / m ² showed a peak. Therefore, the fluorescent molecule-containing nanofibers manufactured by the above steps can reliably detect the presence or absence of the coating layer 2 by setting the amount of application to the base sheet 1 to 0.04 g / m ² or more. However, the light emitted from the nanofibers containing fluorescent molecules can detect weaker light by increasing the sensitivity of the photoreceiver, so the coating layer 2 with a smaller coating amount can be detected by using a more sensitive photoreceiver. In addition, it is possible to detect the presence or absence of the coating layer 2 made of fluorescent molecule-containing nanofibers with a low fluorescent molecule content.

  The above coating sheet is irradiated with light on the surface of the base sheet 1 to cause the fluorescent molecules of the nanofibers to emit light, and whether or not the coating layer 2 is normally laminated is inspected. FIG. 4 shows an inspection method for the coating layer 2. The inspection method in this figure excites fluorescent molecules by irradiating the entire surface of the coating sheet with light. This figure irradiates the coating sheet with visible light of 555 nm in order to excite the rhodamine dye of the fluorescent molecule contained in the nanofiber of the coating layer 2. The excitation light is irradiated on the entire surface, or scanned and irradiated on the entire surface of the coating sheet.

  The rhodamine dye contained in the fluorescent molecule-containing nanofiber of the coating layer 2 is excited by visible light of 555 nm and emits light of 590 nm. The light emission of 590 nm is detected by the light receiver, and it is determined whether or not the coating layer 2 is normally applied to the coating sheet. This is because the coating sheet to which the coating layer 2 is applied emits light of 590 nm. Light emission of the coating layer 2 is detected by a light receiver. In the illustrated light receiver, a filter for attenuating excitation light is disposed in order to remove visible light that is excited from emission of fluorescent molecules. The light receiver includes a light receiving element that detects light emitted from the fluorescent molecules of the coating layer 2 to form an image, and a lens that forms an image of the coating sheet on the light receiving element. The light receiver forms a coating sheet image on the light receiving element with a lens, and determines whether or not the coating layer 2 is present, that is, whether or not the nanofibers are normally applied. When the coating sheet 2 in which the coating layer 2 is not applied to the white portion at the center portion is excited by light and the light emission is detected by a light receiver, the area where the coating layer 2 is not applied does not emit light as shown in FIG. Detected as white. Therefore, it is determined whether the coating layer 2 is normally provided by detecting light emission on the entire surface of the coating sheet with the light receiver.

(1) to (4) in FIG. 5 are concentration diagrams in which the surface of the coating sheet is irradiated with 555 nm light to excite the fluorescent molecules, and the emission of the fluorescent molecules at 590 nm is detected. However, in this coating sheet, a region where the nanofibers are not attached is provided in the white region indicated by a rectangle at the center, thereby clarifying the concentration difference from the attached region of the nanofibers. However, in the coating sheet shown in these figures, nanofibers formed by adding silica nanoparticles containing a rhodamine dye of a fluorescent molecule are attached to a portion excluding the rectangular region at the center of the surface of the substrate sheet 1. . The silica nanoparticles added to the nanofibers are those prepared in Example 1, and the amount of silica nanoparticle added to the nanofibers is 1.02% by weight.
However,
The coating sheet of (1) has a nanofiber adhesion amount of 0.045 g / m ² ,
The coating sheet of (2) has a nanofiber adhesion amount of 0.09 g / m ² ,
The coating sheet of (3) has a nanofiber adhesion amount of 0.135 g / m ² ,
The coating sheet of (4) has a nanofiber adhesion amount of 0.18 g / m ² .

  The coating sheet of the present invention is provided with a coating layer 2 made of nanofibers to realize characteristics that cannot be realized by the base sheet 1 alone, and preferably filters fine particles that are used in a filter and cannot be filtered by a conventional filter, Furthermore, it is reliably inspected whether or not the nanofiber coating layer 2 that cannot be visually confirmed is provided, and is used in an ideal state for various applications.

1 ... Base sheet 2 ... Coating layer

Claims (6)

A coating sheet in which nanofibers are attached to the surface of the base sheet (1) to provide a nanofiber coating layer (2),
The nanofiber is a fluorescent molecule-containing nanofiber containing a fluorescent molecule that emits light when excited ,
And coating sheet wherein nanofibers, to fluorescent molecule containing nanofibers and said to Rukoto containing silica particles containing fluorescent molecule. The coating sheet according to claim 1 ,
The coating sheet whose average particle diameter of the said silica nanoparticle is 1/2 or less of the thickness of the said fluorescent molecule containing nanofiber. The coating sheet according to claim 1 or 2 ,
A coating sheet which is a pre-filtration layer in which the base sheet (1) is a filter paper and the coating layer (2) is attached to the surface of the filter paper to filter and remove finer particles than the filter paper. The coating sheet according to claim 3 , wherein
A coating sheet, wherein the base sheet (1) is a filter for filtering air or liquid for vehicles. A coating sheet according to any one of claims 1 to 4 ,
The coating sheet whose thickness of the said fluorescent molecule containing nanofiber is 800 nm or less, and is 50 nm or more. A method for inspecting a coating sheet obtained by laminating a coating layer (2) made of nanofibers on the surface of a base sheet (1),
A production process for producing fluorescent molecule-containing nanofibers by containing fluorescent molecules that are excited to emit light; and
It comprises a light detection step of exciting the fluorescent molecules of the fluorescent molecule-containing nanofibers and detecting the emission of the excited fluorescent molecules,
In the manufacturing process, the fluorescent molecules are added to the silica nanoparticles and added to the nanofibers,
A method for inspecting a coating sheet, wherein the coating layer (2) is detected by detecting light emitted from a fluorescent molecule-containing nanofiber in the light detection step.