JP2012007954A - Steam permeability evaluation cell and steam permeability evaluation method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a steam permeability evaluation cell and a steam permeability evaluation method, capable of preventing cell cracking in steam permeability evaluation of a test piece for evaluating steam permeability to produce evaluation results with higher reliability.SOLUTION: A steam permeability evaluation cell comprises a corrosive metal layer and a steam impermeable layer having a metal layer composed of a metal impermeable to steam. The steam impermeable layer constitutes an evaluation cell for use in steam permeability evaluation, and comprises a laminate structure having a metal layer composed of a metal impermeable to steam and a buffer layer to prevent cracking composed of an alkaline earth metal. A steam permeability evaluation method using the steam permeability evaluation cell comprises humidifying the evaluation cell and evaluating a corrosion state of the corrosive metal layer to evaluate steam permeability of a test piece.

Description

  The present invention relates to a water vapor permeability evaluation cell and a water vapor permeability evaluation method.

  Conventionally, water vapor permeability, which is one of the important characteristics of plastics, films, sheets, and other packaging materials, is the amount of water vapor that passes through a test piece of unit area per unit time under a given temperature and humidity condition. It is evaluated and measured by a humidity sensor method, a cup method, or the like as a typical test method (see, for example, Non-Patent Documents 1 and 2).

  In recent years, films with good water permeability have been developed for thin films used in displays, etc., and it has become difficult to evaluate in conventional water vapor permeability tests, and is measured by test methods using calcium layers. (For example, refer nonpatent literature 3). However, even in such a method, in a thin film test that requires a high level of water permeability, if it is not properly treated, it will be used for evaluation during the humidification process due to the influence of dust on the test piece and calcium layer. A slight crack may occur in the water-impermeable layer provided on the outer layer of the calcium layer in the cell. If cracks occur even in such a small amount, water vapor enters through the gaps, and an undesired corrosive substance is generated in the calcium layer that is the evaluation standard of the calcium corrosion method. It will affect the characteristics and measurement accuracy. In addition, it may not be easy to confirm whether the corrosive substances generated in the calcium layer are due to water that has permeated the test piece or water that has penetrated from the water-impermeable layer of the outer layer, improving the reliability of the evaluation. It is demanded to make it.

JIS K 7129 JIS Z 0208 G. NISATO at al, SID Conference Record of the International Display Research Conference pp. 1435-8

  In the water vapor permeability evaluation of a test piece for evaluating water vapor permeability, the present invention is capable of preventing cracking of the cell, and provides a water vapor permeability evaluation cell and a water vapor permeation that can obtain a more reliable evaluation result. It provides a sex assessment method.

  In the evaluation cell provided with a corrosive metal layer for evaluating water vapor permeability and a water vapor impermeable layer on the evaluation surface of the test piece, the water vapor impermeable layer transmits water vapor. It has been found that it is possible to prevent the evaluation cell from being cracked by providing a laminated structure having a metal layer made of non-performing metal and a buffer layer for preventing cracking of the metal layer, and the reliability in the evaluation is improved. As a result, the present invention has been completed.

That is, the present invention is based on the water vapor permeability evaluation cell described in the following items (1) to (5) and the water vapor permeability evaluation method described in the following items (6) to (8). Composed.
(1) Evaluation of water vapor permeability in which a test piece includes a corrosive metal layer made of a metal that chemically reacts with water to produce a corrosive substance, and a water vapor impermeable layer having a metal layer made of a metal that does not transmit water vapor. The water vapor impervious layer has a laminated structure having a metal layer made of a metal that does not transmit water vapor and a crack prevention buffer layer made of an alkaline earth metal. A cell for evaluating water vapor permeability.
(2) The water vapor impermeable layer having a metal layer made of a metal that does not transmit water vapor in the water vapor impermeable layer has a laminated structure having the crack preventing buffer layer between two metal layers made of a metal that does not transmit water vapor. The cell for evaluating water vapor permeability according to item (1).
(3) In the water vapor impermeable layer, the water vapor impermeable layer having a metal layer made of a metal that does not transmit water vapor is composed of at least two types of metal layers. The water vapor permeability evaluation cell according to item (1) or item (2).
(4) The water vapor impermeable layer having a metal layer made of a metal that does not transmit water vapor in the water vapor impermeable layer is a metal layer made of a metal alloy that does not transmit water vapor. Item 1. A cell for evaluating water vapor permeability according to any one of Items 1 to 3.
(5) The corrosive metal layer made of a metal that chemically reacts with water in the water vapor impermeable layer to produce a corrosive material contains an alkaline earth metal or an alkali metal according to items (1) to (4). The cell for water vapor permeability evaluation according to any one of the above items.
(6) Using the water vapor permeability evaluation cell according to any one of items (1) to (5), the evaluation cell is humidified, and chemically reacted with water to cause corrosives. A method for evaluating water vapor permeability, wherein the water vapor permeability of a test piece is evaluated by evaluating the corrosion state of a resulting corrosive metal layer.
(7) The evaluation of the corrosion state is to directly evaluate the surface of the corrosive metal layer that comes into contact with the test piece and generates a corrosive substance by chemically reacting with water, thereby evaluating the defective part of the test piece. The water vapor permeability evaluation method according to item (6).
(8) The corrosion state is evaluated by passing the test piece from the volume of the corroded metal calculated from the corroded metal area and the corroded metal thickness in the corrosive metal layer that reacts with water to produce the corroded material. The method for evaluating water vapor permeability according to item (7), wherein the moisture content is quantified.

  According to the water vapor permeability evaluation cell of the present invention, it is possible to prevent cracking of the cell in the water vapor permeability evaluation of a test piece for evaluating water vapor permeability, and an evaluation result having higher reliability can be obtained. . The present invention relates to a water vapor permeability evaluation cell and a water vapor permeability evaluation method.

It is a schematic diagram for demonstrating an example of the structure of the water vapor permeability evaluation cell of this invention.

  The present invention comprises a test piece comprising a corrosive metal layer made of a metal that chemically reacts with water to produce a corrosive substance and a water vapor impermeable layer having a metal layer made of a metal that does not transmit water vapor. An evaluation cell used for evaluation, wherein the water vapor impermeable layer has a laminated structure having a metal layer made of a metal that does not transmit water vapor and a crack prevention buffer layer made of an alkaline earth metal. It is a water vapor permeability evaluation cell characterized by having a buffer layer for preventing cracking of a metal layer made of a metal that does not transmit water vapor. It is possible to improve the property. In the water vapor permeability evaluation cell of the present invention, the water vapor impermeable layer includes an alkaline earth metal layer that is a crack prevention buffer layer between the water vapor impermeable metal layer and another water vapor impermeable metal layer. By constituting a laminated structure having a sandwich shape, the effect of preventing cracking of the evaluation cell is more easily exhibited.

  Further, the present invention uses the above-mentioned water vapor permeability evaluation cell, humidifies the evaluation cell, and evaluates the corrosion state of the corrosive metal layer that chemically reacts with water to generate a corrosive substance. The water vapor permeability of the piece can be evaluated. In the evaluation of water vapor permeability, when a test piece for evaluating water vapor permeability incorporated in a water vapor permeability evaluation cell permeates water vapor, the water vapor chemically reacts with the water to generate corrosives. The corrosive metal layer is reached, and the corrosive metal layer undergoes a corrosion reaction to generate a corrosive substance. Therefore, the generated corrosive substance is evaluated. As a more detailed evaluation, by calculating the volume of the corrosive substance, the amount of water permeated through the test piece can be quantified to obtain the water vapor transmission rate.

An example of the structure of the water vapor permeability evaluation cell of the present invention will be described with reference to the drawings.
FIG. 1 shows a test piece for evaluating water vapor permeability of the present invention, a corrosive metal layer (hereinafter referred to as a corrosive metal layer) made of a metal that chemically reacts with water to generate a corrosive substance, and a metal that does not transmit water vapor. And a water vapor impermeable layer (hereinafter referred to as a water vapor impermeable layer), wherein the water vapor impermeable layer comprises a metal layer that does not transmit water vapor (hereinafter referred to as a water vapor impermeable metal layer) and a water vapor impermeable metal. It is a schematic diagram which shows an example of the cell for evaluation provided with the laminated structure which has a crack prevention buffer layer (henceforth a crack prevention buffer layer) of a layer.

  In the evaluation cell of the present invention, the corrosive metal layer 2 is provided at a predetermined position on the evaluation surface of the test piece 1 for evaluating water vapor permeability such as a film, and then the water vapor impermeable layer 6 is provided. . The water vapor impermeable layer 6 is provided with a first water vapor impermeable metal layer 3 so as to cover the corrosive metal layer 2, and further a crack preventing buffer layer 4 so as to cover the first water vapor impermeable metal layer 3. And a laminated structure in which the second water vapor impermeable metal layer 5 is provided so as to cover the crack preventing buffer layer 4. The structure of the water vapor impermeable layer is a laminated structure having a crack preventing buffer layer between the two water vapor impermeable metal layers, but is not limited to the structure shown in the drawing. The layer may be one type or two or more types of metal layers.

  As a test piece used for the evaluation of the present invention, one having a film shape, a sheet shape, a plate shape, a block shape or the like can be used. In the water vapor permeability evaluation of the present invention, a single-layer or composite moisture-proof film or sheet used for food or electronic parts, a metal vapor-deposited film, a waterproof sheet for building materials, an assembly part, or the like is generally applied.

Next, an example of how to make the evaluation cell of the present invention will be described using an example of the above structure.
First, a test piece 1 for evaluating water vapor permeability is prepared, and a corrosive substance is chemically reacted with water at a predetermined position on the surface to be evaluated of the test piece, usually the surface opposite to the surface in contact with water vapor. Using the resulting metal, the corrosive metal layer 2 can be formed by a method such as vapor deposition. Next, a water vapor impermeable layer 6 is formed. First, a first water vapor impermeable metal is formed by a method such as vapor deposition using a metal that does not transmit water vapor so as to cover the corrosive metal layer 2 on the test piece. Layer 3 can be formed.

  Next, a crack-preventing buffer metal layer 4 is formed by vapor deposition in the same manner as described above using an alkaline earth metal so as to cover the first water vapor-impermeable metal layer 3, and the crack-preventing buffer layer 4 is further formed. The water vapor impermeable layer 6 can be formed by forming the second water vapor impermeable metal layer 5 by vapor deposition in the same manner as described above using a metal that does not transmit water vapor so as to cover the surface.

  Next, in the test piece 1 in which the corrosive metal layer 2 and the water vapor impermeable layer 6 obtained above are formed, at least when the corrosive metal layer 2 and the water vapor impermeable layer 6 are exposed to water vapor, In order not to come into contact with the surface, portions other than the water vapor contact surface are sealed with resin, glass, metal, or the like, whereby an evaluation cell can be obtained.

  Examples of the metal that generates a corrosive substance by chemically reacting with water include alkali metals such as lithium, sodium, potassium, rubidium, cesium and francium, alkaline earth metals such as magnesium, calcium, strontium, barium and radium, and Includes metals having a high ionization tendency such as aluminum, iron and lead. Among these, an alkaline earth metal or an alkali metal is preferable, an alkaline earth metal is more preferable, and among these, barium or calcium is preferable. Moreover, as a particle diameter of these metals, the thing about 1-5 mm can be used.

As a method for producing the corrosive metal layer, for example, a known vapor deposition method such as a vacuum vapor deposition method, a sputtering vapor deposition method, or an ioplating method can be used.
The thickness of the corrosive metal layer is preferably 30 nm to 500 nm, and the thickness of each corrosive metal layer may be the same or different.

  The metal that does not transmit water vapor may be any metal that does not transmit water vapor and that does not chemically react with water to produce a corrosive substance, such as aluminum, zinc, tin, indium, lead, silver, and copper. An alloy containing these metals may be used. Among these, aluminum and silver are preferable. As these metals, different metals can be used in the water vapor impermeable layer.

  Examples of the alkaline earth metal used for the anti-cracking buffer layer include magnesium, calcium, strontium, barium, and radium. Among these, barium or calcium is preferable. Moreover, the crack of a water vapor | steam impermeable layer can also be confirmed by using the metal which chemically reacts with water and produces a corrosive substance for a crack prevention buffer layer.

  In the production of the water vapor impermeable layer, the vapor deposition method similar to the method of producing the corrosive metal layer can be used as a method for producing the water vapor impermeable metal layer and the crack-preventing buffer metal layer. A thermal spraying method can be used.

The thickness of the water vapor impermeable metal layer is preferably 500 nm to 20 μm, and the thickness of each water vapor impermeable metal layer may be the same or different.
Moreover, as thickness of a crack prevention buffer layer, 10 nm-800 nm are preferable.

As the resin that seals the portion other than the water vapor contact surface, in order to protect the surface of the water vapor impermeable layer of the evaluation cell, conditions for humidification during the evaluation, for example, a temperature of 40 ± 0.5 ° C., As long as the evaluation cell is exposed for 24 hours under a relative humidity of 90 ± 2%, the mass change of the sealing resin may be an organic substance that is 1 mg or less per exposed area of 50 cm ^2. , Beeswax, carnauba wax, paraffin wax and the like.

  As a method for sealing a portion other than the water vapor contact surface, for example, a resin mixture in which beeswax and paraffin are melt-mixed at a ratio of 1: 1 is melted and used as a molten resin, and at least the outermost layer is used. After the resin layer is formed by contact so that the entire exposed surface of the water vapor impermeable metal layer (water vapor impermeable layer) can be covered, the resin layer can be cooled and solidified for sealing. Further, by using a combination of a glass plate or a metal plate and a molten resin, the corrosive metal layer and the water vapor impermeable layer can be sealed by fixing the glass plate or the metal plate with a resin.

Next, an example of how to use the water vapor permeability evaluation cell of the present invention will be described.
As an example of a method for evaluating the water vapor permeability of a test piece using the water vapor permeability evaluation cell of the present invention, first, the above evaluation cell is prepared, so that the water vapor contacts the water vapor contact surface, It arrange | positions in a constant temperature and humidity tank, and performs a humidification process on predetermined conditions.

  As the humidification treatment conditions, it is preferable to carry out under arbitrary conditions below the melting point of the sealing resin. For example, the temperature can be 40 ± 0.5 ° C. and the relative humidity can be 90 ± 2%.

  By preparing each cell for evaluation in which such a humidification treatment is performed at every measurement time and evaluating the corrosion state of the corrosive metal layer, the water vapor permeability of the test piece can be evaluated. Further, every time the humidifying treatment time elapses, the evaluation cell can be taken out to evaluate the corrosion state of the corrosive metal layer.

  Moreover, as a method of evaluating such a corrosion state, a method of directly evaluating the surface of the corrosive metal layer in contact with the test piece to evaluate a defective portion (generated corrosion product) of the test piece can be mentioned. Furthermore, the amount of moisture that has permeated through the test piece can be quantified from the volume of the corroded metal calculated from the area of the corroded material and the thickness of the corroded metal layer.

As a method of quantifying the amount of water that has passed through the test piece, the corrosive metal layer chemically reacts with moisture by the humidification treatment, so that the corrosive metal layer having a valence of a is represented by the following chemical formula (1). One mole of the constituent metal M reacts with a mole of water to produce one mole of metal hydroxide.
M + aH ₂ O → M (OH) a + (a / 2) H ₂ chemical formula (1)

From this, the water content permeated through the test piece can be expressed as water vapor permeability (unit: g / m ² / day) converted per unit area per day. , Humidity treatment time, Area of corrosive metal layer of water vapor permeability evaluation cell, Area of corrosive metal layer formed on corrosive metal layer after humidification treatment and thickness of corrosive metal layer, Metal hydroxide after corrosion From the density, it can be calculated by the following formula (1).
Water vapor permeability = X * 18 * a * (10000 / A) * (24 / T) Formula (1)

In the above formula (1), T is constant temperature and humidity treatment time (hours), A is the area (cm ² ) of the corrosive metal layer, t is the thickness (cm) of the corrosive metal layer, and δ is the corrosive metal. The area (cm ² ) of the metal corrosive material generated in the layer, d is the metal hydroxide density (MOH) after corrosion (g / cm ³ ), a is the valence of the metal constituting the corrosive metal layer, X represents the molar mass (g / mol) of the metal corrosion product (metal hydroxide) generated by the humidification treatment obtained by the following mathematical formula (2).
X = (δ * t * d) / Mw Formula (2)
In the above formula (2), Mw represents the molecular weight (formula weight) of the metal corrosive (metal hydroxide) generated in the corrosive metal layer, and δ, t, and d are the same as those in the formula (1). Represents.

  EXAMPLES Hereinafter, although an Example demonstrates this invention concretely, this invention is not limited at all by these examples.

Example 1
(1) Preparation of water vapor permeability evaluation cell As a test piece, a water vapor impermeable film having a two-layer structure consisting of a polyethersulfone film (thickness 200 μm) and a SiO ₂ layer (inorganic layer, thickness 50 nm) is prepared. In the center of one surface of the test piece, metal calcium (divalent) is used as a corrosive metal, and the area is 2.0 mm × 2.0 mm by a vacuum evaporation apparatus (JEOL vacuum evaporation apparatus JEE-400). Thus, a corrosive metal layer having a thickness of 200 nm was formed. Next, a first water vapor impermeable metal layer having a thickness of 4 μm was formed by vacuum vapor deposition similar to the above using metal aluminum so as to cover all of the exposed surface of the corrosive metal layer. Next, a crack-preventing buffer metal layer having a thickness of 50 nm was formed by vacuum deposition using barium metal (divalent) so as to cover all exposed surfaces of the first water vapor impermeable metal layer. Then, a second water vapor impermeable metal layer having a thickness of 1 μm was formed by vacuum deposition using silver so as to cover all of the exposed surface of the anti-cracking metal layer. Next, using a resin in which beeswax (melting point: 60 to 62 ° C.) and paraffin (melting point: 60 to 62 ° C.) were melt-mixed at a ratio of 1: 1, The two water vapor impermeable metal layers were all in contact with each other, the resin was cooled and solidified, and sealed to produce a water vapor permeability evaluation cell. In addition, the film of the test piece used what formed the inorganic layer by sputtering.

(2) Evaluation of water vapor permeability Using the water vapor permeability evaluation cell obtained above, this was placed in a constant temperature and humidity chamber at 40 ° C and a humidity of 90% for 300 hours and treated by constant temperature and humidity (humidification treatment) ) After the humidification treatment, images of 2.0 mm × 2.0 mm were taken and recorded with a laser microscope for the formation of corrosives in the first corrosive metal layer. In the corroded portion, metallic calcium reacted with moisture to form calcium hydroxide, and when photographed, it was observed as a discolored or white portion. Prior to the humidification treatment, the generation of the corrosive material in the corrosive metal layer of the water vapor permeability evaluation cell was compared with an image recorded by a laser microscope as a reference, and the constant temperature and humidity treatment was performed for 500 hours. The total area of the corroded area was measured. Corrosion having a diameter of 50 to 150 μm was confirmed in the corrosive metal layer having an area of 2.0 mm × 2.0 mm after treatment for 500 hours at constant temperature and humidity, and the total corrosion area was 5.1 × 10 ⁻⁴ cm ² . Since the molecular weight and density of calcium hydroxide observed as corrosion were 76.1 and 2.24 g / cm ³ , the molar mass of the produced calcium hydroxide was 3.00 × ^{10 −10} g / mol. From these, the water vapor transmission rate was determined to be 2.2 × 10 ⁻⁴ (g / m ² / day). Although the vicinity of the corroded portion was observed, no crack was observed in the water vapor impermeable layer, and it was found that the water vapor permeability evaluation cell functioned normally.

(Example 2)
(1) Production of Water Vapor Permeability Evaluation Cell In Example 1, except that the metal aluminum used for forming the first water vapor impermeable metal layer was used for the second water vapor impermeable metal layer. In the same manner, a water vapor permeability evaluation cell was produced.

(2) Evaluation of water vapor permeability Similar to Example 1 except that the water vapor permeability evaluation cell obtained above was used and the mounting time of the constant temperature and humidity chamber in Example 1 was changed from 300 hours to 400 hours. The water vapor permeability was evaluated by the operation of
As a result of confirming the formation of corrosives in the corrosive metal layer after the humidification treatment, calcium hydroxide, which is a discolored or white corroded corrosive, was observed. Corrosion with a diameter of 60 to 160 μm can be confirmed in the corrosive metal layer having an area of 2.0 mm × 2.0 mm after treatment for 600 hours at constant temperature and humidity, and the total corrosion area is 5.6 × 10 ⁻⁴ cm ^2. It was. The molar mass of calcium hydroxide calculated from this was 3.30 × 10 ⁻¹⁰ g / mol. From these, the water vapor transmission rate was determined to be 1.8 × 10 ⁻⁴ (g / m ² / day). Although the vicinity of the corroded portion was observed, no cracks were observed in the water vapor impermeable layer, indicating that the water vapor permeability evaluation cell functioned normally.

(Example 3)
(1) Fabrication of vapor permeability evaluation cell In Example 1, except that a test piece in which foreign particles having a diameter of about 100 μm to about 500 μm were adhered to a water vapor impermeable film was used. Thus, a water vapor permeability evaluation cell was produced.

(2) Evaluation of water vapor permeability Similar to Example 1 except that the water vapor permeability evaluation cell obtained above was used and the time for placing the constant temperature and humidity chamber in Example 1 was changed from 300 hours to 450 hours. The water vapor permeability was evaluated by the operation of
As a result of confirming the formation of corrosives in the corrosive metal layer after the humidification treatment, calcium hydroxide, which is a discolored or white corroded corrosive, was observed. Corrosion with a diameter of 50 to 140 μm can be confirmed in the corrosive metal layer having an area of 2.0 mm × 2.0 mm after being treated for 700 hours at constant temperature and humidity, and the total corrosion area is 3.6 × 10 ⁻⁴ cm ^2. It was. The molar mass of calcium hydroxide calculated from this was 2.12 × 10 ⁻¹⁰ g / mol. From these, when the water vapor permeability was determined, it was 1.0 × 10 ⁻⁴ (g / m ² / day). Although the vicinity of the corroded portion was observed, no crack was observed in the water vapor impermeable layer, and it was found that the water vapor permeability evaluation cell functioned normally.

(Comparative Example 1)
(1) Production of water vapor permeability evaluation cell In Example 1, using a test piece in which foreign particles having a diameter of about 100 μm to about 500 μm were adhered on a water vapor impermeable film, the water vapor impermeable layer was prevented from cracking. A water vapor permeability evaluation cell was prepared in the same manner as in Example 1 except that the buffer metal layer and the second water vapor impermeable metal layer were not formed.

(2) Evaluation of water vapor permeability Water vapor permeability was evaluated by the same operation as in Example 1 using the water vapor permeability evaluation cell obtained above.
As a result of confirming the formation of corrosives in the corrosive metal layer after the humidification treatment, calcium hydroxide, which is a discolored or white corroded corrosive, was observed. Corrosion with a diameter of 100 to 580 μm was confirmed in a 2.0 mm × 2.0 mm size calcium thin film after treatment for 500 hours at constant temperature and humidity, and the total corrosion area was 7.5 × 10 ⁻³ cm ² . The molar mass of calcium hydroxide calculated from this was 4.42 × 10 ⁻⁹ g / mol. From these, the water vapor transmission rate was determined to be 3.2 × 10 ⁻³ (g / m ² / day). When the vicinity of the corroded portion was observed, cracks were observed in the water vapor impermeable layer, and it was found that the water vapor permeability evaluation cell did not function normally.

DESCRIPTION OF SYMBOLS 1 Test piece 2 Corrosive metal layer 3 1st water vapor impermeable metal layer 4 Crack prevention buffer metal layer 5 2nd water vapor impermeable metal layer 6 Water vapor impermeable layer

Claims (8)

  Evaluation used for water vapor permeability evaluation, comprising a test piece with a corrosive metal layer made of a metal that chemically reacts with water to produce a corrosive substance and a water vapor impermeable layer having a metal layer made of a metal that does not transmit water vapor. The water vapor impermeable layer has a laminated structure having a metal layer made of a metal that does not transmit water vapor and a crack prevention buffer layer made of an alkaline earth metal. Permeability evaluation cell.   The water vapor impermeable layer having a metal layer made of a metal that does not transmit water vapor in the water vapor impermeable layer has a laminated structure having the crack preventing buffer layer between two metal layers made of a metal that does not transmit water vapor. Item 2. A cell for evaluating water vapor permeability according to Item 1.   2. The water vapor impermeable layer having a metal layer made of a metal that does not transmit water vapor in the water vapor impermeable layer, wherein the metal layer made of a metal that does not transmit water vapor comprises at least two kinds of metal layers. Or the water vapor permeability evaluation cell according to 2.   4. The water vapor impermeable layer having a metal layer made of a metal that does not transmit water vapor in the water vapor impermeable layer, wherein the metal layer made of a metal that does not transmit water vapor is made of a metal alloy. The water vapor permeability evaluation cell according to claim 1.   The water vapor permeation according to any one of claims 1 to 4, wherein the corrosive metal layer made of a metal that chemically reacts with water in the water vapor impermeable layer and generates a corrosive material contains an alkaline earth metal or an alkali metal. Sex evaluation cell.   Using the water vapor permeability evaluation cell according to any one of claims 1 to 5, the evaluation cell is humidified, and a corrosive state of a corrosive metal layer that chemically reacts with water to generate a corrosive substance is obtained. A water vapor permeability evaluation method for evaluating the water vapor permeability of a test piece by evaluation.   The evaluation of the corrosion state is to evaluate a defective portion of the test piece by directly observing the surface of the corrosive metal layer that is in contact with the test piece and generates a corrosive substance by chemically reacting with water. The water vapor permeability evaluation method described in 1.   The evaluation of the corrosion state further includes the amount of moisture permeated through the specimen from the volume of the corroded metal calculated from the corroded metal area and the corroded metal thickness in the corrosive metal layer that reacts with water to produce corrosive. The water vapor permeability evaluation method according to claim 7, wherein the water vapor permeability is quantified.

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