JP2018021813A - Gas barrier test method and test jig - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable a test piece to be tested in a state close to a form of a product, in gas barrier test.SOLUTION: A gas barrier test method uses a gas barrier test device to perform gas permeation test of a test piece F comprising a tested film or sheet configured to form a container or various films. One test unit in the gas barrier test device is configured to: circulate permeation test object gas and carrier gas, which is used to measure gas permeability of the testing piece, through two spaces partitioned by the test piece F; permeate the test piece F in the carrier gas; and measure entering permeation object gas, to thereby measure permeability of the permeation object gas. The test piece F is fixed to the test unit in a state where stress is applied with the test piece kept curved, and then the gas barrier test is performed.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a jig provided in a gas barrier test apparatus used in a performance evaluation test of a gas barrier film (especially gas permeability) of a protective film for an organic solar cell or an organic EL, which prevents water and oxygen molecules from permeating. Then, for example, the present invention relates to a test jig and a test method used for a cell or unit when a gas barrier film in which an inorganic compound is formed on a resin film is set as a test piece in one cell or unit. .

  Currently used gas barrier test apparatuses are capable of performing gas barrier tests on packaging films and solar cell backsheets, that is, permeation performance tests of various gases such as water vapor, oxygen, and carbon dioxide.

  For example, when a gas permeability test is performed on a plastic packaging material, the film to be tested is disposed in one unit, chamber, or cell, and one of the two chambers partitioned by the film to be tested. A gas containing a target gas for the permeation test is allowed to flow into the inside, and a carrier gas not containing the target gas for the permeation test is allowed to flow into the other chamber. A sensor measures the permeation amount of the permeation test target gas entering the carrier gas, and performs a gas permeability test of the film under test.

The applicant of the present application previously proposed such a gas barrier test apparatus as shown in FIGS. 4 and 5 (Japanese Patent Application No. 2006-7355).
FIG. 4 is an exploded explanatory view of the gas barrier test apparatus.
FIG. 5 is a cross-sectional explanatory view of the B cell of the gas barrier test apparatus.

  This gas barrier test apparatus 30 is a water vapor permeation test apparatus, and an A cell 32 and a B cell 31 that can set a film to be tested on the front side of the front are provided at symmetrical positions on the left and right.

  Although the internal structure will be described with reference to FIG. 5, the outer sides of the A cell 32 and the B cell 31 are covered with cell outer covering members 31 s and 32 s, and the rotating frame bodies 12 and 12 of the cell fixing jig 10. The coverings of the cell outer covering members 31s and 32s are pressed and fixed by the fixing means 13 at the tip end portion.

Connected to each of the cells 31 and 32 is an introduction pipe for feeding a carrier gas and an introduction pipe for feeding a gas containing a predetermined concentration of water vapor as a gas under test.
These introduction pipes and lead-out pipes can also be arranged inside the device 30.

  Inside the cells 31 and 32, the gas containing the carrier gas and water vapor is fed into each of the two chambers partitioned by the set film to be tested, and the amount of water vapor in the derived carrier gas is measured by a sensor. The test is then performed.

First, a film holding plate 33 is disposed inside the film under test F.
The film F to be tested is bonded and held on the film holding plate 33 and bonded to the right side surface portion of the mounting portion 40 of the gas barrier test apparatus 30 in the drawing.

A fixing magnet sheet 34 is arranged outside the film F to be tested, and the cell outer covering member 31s is joined from the outside.
The fixing means 13 can press and fix the substantially central portion 31c of the cell outer covering member 31s.

An inlet 35 for introducing a carrier gas is provided in a portion of the mounting portion 40 of the gas barrier test apparatus 30 that covers the cell outer covering member 31s on the right side surface in the drawing, and the carrier gas is led out below the portion. A lead-out port 36 is provided.
In the figure, reference numeral 44 denotes an introduction path through which a gas under test including a permeation test target gas (water vapor here) for conducting a permeation test is introduced, and 45 denotes a lead-out path through which the gas under test is derived. ing.

  Therefore, when the cell outer covering member 31s of the B cell 31 is fixed to the mounting portion 40 of the gas barrier test apparatus 30, a small chamber is formed on the side of the mounting portion 40 inside by the film F to be tested. The carrier gas is introduced from the gas introduction port 35, and the carrier gas containing water vapor that has passed through the film F to be tested is led out from the outlet port 36.

  By detecting and measuring the amount of water vapor contained in the derived carrier gas with a sensor, the water vapor transmission performance of the film F to be tested is tested.

  FIG. 5 is a cross-sectional explanatory view of the B cell portion, and a carrier gas inlet 35 and outlet 36 are provided in the recess 41 of the mounting portion 40 of the gas barrier test apparatus.

  As described above, the film F to be tested is bonded to the inner side with the film holding plate and the outer side with the magnet sheet, and the outer cell covering member 31s is bonded and fixed from the outer side.

  Thus, the inner small chamber 42 is formed in the recess 41 portion of the mounting portion 40 by bonding the film to be tested F to the side surface of the mounting portion 40 and fixing the cell outer covering member 31s.

On the other hand, an outer chamber 43 is formed outside the film F to be tested.
In this outer small chamber 43, a conduction path is formed from the mounting portion 40 to the cell outer covering member 31s, and this conduction path becomes an introduction path 44. From this introduction path 44, for example, nitrogen gas containing water vapor or the like is tested. Gas for use is introduced.

On the other hand, a lead-out path 45 for leading the nitrogen gas containing water vapor from the outer small chamber 43 is formed, and the gas under test containing water vapor having a predetermined concentration flows through the outer small chamber 43.
Since nitrogen gas as a carrier gas is circulated in the inner small chamber 42, water vapor that has passed through the film F to be tested is included in the carrier gas, flows into the sensor, and is measured. It becomes.

  As described above, the film F to be tested is set in the B cell 31, the gas to be tested including the permeated gas to be measured is circulated in the outer small chamber 43, and the carrier gas is circulated in the inner small chamber 42. The gas permeation performance of the film F to be tested can be tested by detecting and measuring the permeate gas into the latter carrier gas.

The above configuration is exactly the same as the configuration of the A cell 32 provided on the opposite side, and has a symmetrical structure.
The cell fixing jig 10 presses and fixes the cell outer covering members 31s and 32s forming the A cell 32 and the B cell 31 from the outside.

  As in the above conventional example, in a conventional gas barrier test apparatus, a film to be tested is fixed in a flat state, and a gas containing a carrier gas and a permeation test target gas is circulated on both sides of the film to be tested. Thus, the permeability of the permeation test target gas was measured by measuring the permeation target gas contained in the carrier gas.

  However, the actual product has various forms such as a display with a curved surface and a bottle shape, such as a cylindrical shape, a substantially quadrangular prism shape with rounded corners, or a body portion. There are various forms such as those having a constricted portion, etc., and it is understood that there is a curved portion on the side surface portion of the product, and the portion that is formed in a completely flat shape is a part of it. .

  Therefore, in the present invention, when a film or sheet-like test piece is set in a test cell or test unit in a test with a conventional gas barrier test apparatus, it is not simply set in a flat shape but in a curved shape. In other words, it is an object of the present invention to enable the test piece to be tested under the same conditions in the same form as the actual product in a state where stress is applied to the test piece.

In order to solve the above-mentioned problems, the first one of the present invention is a gas barrier test in which a gas permeability test is performed on a test piece which is a film to be tested or a test sheet to form a container or various films, using a gas barrier test apparatus. A carrier gas for measuring a permeation test target gas and gas permeability of the test piece in two spaces partitioned by the test piece in one test unit or test cell in the gas barrier test apparatus In the gas barrier test method using the gas barrier test apparatus for measuring the permeability of the permeation target gas by measuring the permeation target gas that has penetrated the test piece into the carrier gas and has entered the carrier gas,
In the gas barrier test method, the gas barrier test is performed by fixing the test piece in a curved state and applying stress to the test unit or the test cell.

The second one of the present invention is for a gas barrier test of a test piece that can be set in a test unit or a test cell in a curved state of a test piece that is a film to be tested or a sheet to be tested that forms a container or various films. A jig,
The test piece has a flow path through which the carrier gas can flow in the main body, one side surface thereof is formed in a curved shape, a through hole is formed in the one side surface, and the through hole is covered. The test piece pressing block is provided with an inlet and a discharge port for the permeation test target gas, and further provided with a test piece pressing block having a space inside. A gas barrier test jig characterized in that a permeation target gas can be measured by circulating a permeation test target gas and measuring a carrier gas containing the permeation test target gas that has passed through the test piece.

  The first aspect of the invention is a gas barrier test method for performing a gas permeability test of a test piece which is a film to be tested or a sheet to be tested to form a container or various films using a gas barrier test apparatus, the gas barrier test apparatus In one test unit or the like, a permeation test target gas and a carrier gas for measuring the gas permeability of the test piece are circulated in two spaces partitioned by the test piece, and the test is conducted in the carrier gas. In a gas barrier test method using a gas barrier test apparatus that measures the permeability of the permeation target gas by measuring the permeation target gas that has permeated through and penetrated the piece, stress is applied while the test piece is bent. In this state, the gas barrier test is performed by fixing the test unit to the test unit. In order to be able to carry out the gas barrier test in the same form as more product pieces, it become possible to test the gas permeability of the more practical product.

According to a second aspect of the present invention, there is provided a measurement tool for a curved test piece that can be set in a test unit by bending a test piece made of a film to be tested or a sheet to be tested that forms a container or various films. The main body part has a flow path through which the carrier gas can be circulated, and one side surface thereof is formed in a curved shape, and a through hole is formed on the one side surface so that the through hole is covered. The pieces are joined airtight, and the periphery of the test piece can be pressed, and a holding block having a space inside is provided. The holding block is provided with an inlet and a discharge port for the permeation test object gas, and the permeation test object. A gas barrier test jig capable of measuring a permeation target gas by measuring a carrier gas including a permeation test target gas that has been passed through the test piece.
With this measuring jig, a gas barrier test can be carried out according to the actual product form, as in the first invention.

It is a cross-sectional schematic diagram of the jig | tool for a gas barrier test in the gas barrier test apparatus which concerns on this invention. It is a whole perspective schematic diagram of the state where the test piece pressing block of the above-mentioned gas barrier test jig was removed. It is a see-through | perspective plane schematic diagram of the said jig | tool for a gas barrier test. It is decomposition | disassembly explanatory drawing of the conventional gas barrier test apparatus. It is sectional explanatory drawing of the B cell of the said conventional gas barrier test apparatus.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.
FIG. 1 is a schematic cross-sectional view of a gas barrier test jig in a gas barrier test apparatus according to the present invention.
FIG. 2 is an overall perspective schematic view of the gas barrier test jig with the test piece pressing block removed.
FIG. 3 is a perspective plan view of the gas barrier test jig.

  The gas barrier test jig 20 covers a bowl-shaped cell block 21 having an internal space and a through hole 22 provided in the curved surface of the cell block 21, and a test film stretched over the through hole 22. And a test piece pressing block 24 for pressing the peripheral edge of the test piece F such as a test sheet.

As described above, the cell block 20 has a bowl-like appearance, and is provided with an inlet 21i for introducing a carrier gas and an outlet 21h for discharging the carrier gas at both ends thereof.
Further, a through hole 22 is provided in the curved surface 21 w of the cell block 20, and a test piece F is stretched so as to cover the through hole 22.

The test piece pressing block 24 holds the peripheral edge of the test piece F.
A recess is formed inside the test piece pressing block 24, and the peripheral edge portion of the test piece F can be hermetically joined to the curved surface 21 w of the cell block 21 and pressed by the test piece pressing block 24.

The O-ring 26 is disposed on the peripheral edge of the test piece F, and the test piece F can be pressed airtight by the test piece pressing block 24.
Therefore, the space 27 is formed above the test piece F by setting the test piece F in the cell block 21 in an airtight manner by the test piece pressing block 24.

  The test piece presser block 24 is provided with an introduction port 24 i through which a permeation test target gas is introduced and a discharge port 24 h through which this gas is discharged, and the test target gas can be circulated in the space portion 27.

  Various conventional means can be used as means for fixing the test piece presser block 24 to the cell block 21, and fixing means such as screws, clips and retaining bands can be used.

Further, the O-ring 26 may not be provided over the entire periphery of the test piece F, but may be provided in a part thereof.
Next, the test procedure will be described.

First, the test piece F is joined to the peripheral portion of the through hole 22 so as to cover the through hole 22 of the cell block 21 from the outside.
At this time, the test piece is joined in a curved state along the curved surface 21 w of the cell block 21.

  Next, an O-ring 26 is disposed on the peripheral edge of the test piece F, the test piece presser block 24 is joined thereon, and the test piece presser block 24 is fixed by fixing means such as screws.

Here, when the test piece F made of the film is joined to the cell block, an adhesive tape can be used.
That is, it is possible to cut the test piece F one size larger in accordance with the size of the substantially rectangular through-hole 22 and adhere the test piece F to the peripheral portion of the through-hole 22 with an adhesive tape on its four sides.

Thereafter, the test piece presser block 24 can be fixed.
In adhering the test piece F to the peripheral portion of the through hole 22, it is also possible to apply grease to the peripheral portion of the through hole 22.
In addition, when changing the curvature of the test piece F, it is only necessary to prepare several types having different radius lengths of the curved surface 21w of the bowl-shaped cell block 21.

  After the test piece F is set in the gas barrier test jig 20 as described above, a carrier gas, for example, nitrogen gas is introduced from the introduction port 21i of the cell block 21, and the carrier gas is discharged from the discharge port 21h. On the other hand, from the introduction port of the test piece presser block 24, for example, water vapor having a predetermined humidity, which is a permeation target gas, is introduced, and the water vapor is discharged from the discharge port 21h. The test piece F passes through the space 27, enters the internal space of the cell block 21, and the carrier gas containing water vapor as the permeation target gas is discharged from the discharge port 21h of the cell block 21, and is included in the carrier gas. The gas barrier performance of the test piece F can be tested by measuring the amount of the water vapor.

As mentioned above, although embodiment of this invention was described, in this invention, various design changes can be performed as follows.
The cell block has a bowl shape in the above embodiment, but its shape and size can be changed as necessary.

In short, it is only necessary that a part thereof has a curved surface with an appropriate curvature and a through hole is provided in the curved surface.
An actual test apparatus may be configured such that two gas barrier test jigs are attached so that two test pieces can be tested simultaneously.

The configuration of the test piece holding block for setting and fixing the test piece F in the through hole of the cell block can also be designed freely. A space is provided inside, and an introduction port and a discharge port for introducing the permeation test target gas are provided. An exit may be provided.
The test piece pressing block can be fixed to the cell block using various fixing means.

  When joining the test piece to the through hole of the cell block, the test piece may be bonded to the periphery of the test piece using a double-sided adhesive tape. In short, the test piece is airtightly covered with the through hole portion. And can be fixed by a test piece presser block.

  As described above, in the present invention, the test piece is bent and set in the cell block so that the gas barrier test can be performed, thereby performing the gas permeation test in a state closer to a real product. We were able to propose a test method and a test jig that made it possible.

DESCRIPTION OF SYMBOLS 10 Cell fixing jig 13 Fixing means 20 Gas barrier test jig 21 Cell block 21i Inlet 21h Outlet 21w Curved surface 22 Through hole 24 Test piece pressing block 24i Inlet 24h Outlet 26 O-ring 27 Space 30 Gas barrier Test device 31 B cell 31 s, 32 s Cell outer covering member 32 A cell 33 Film holding plate 34 Magnet sheet 35 Inlet port 36 Outlet port 40 Mounting portion 41 Recess 42 Inner chamber 43 Outer chamber 44 Inlet channel 45 Outlet channel

Claims (2)

A gas barrier test method for performing a gas permeability test on a test piece which is a film to be tested or a test sheet to form a container or various films, using a gas barrier test apparatus, wherein one test unit or test in the gas barrier test apparatus In the cell, a permeation test target gas and a carrier gas for measuring the gas permeability of the test piece are circulated in two spaces partitioned by the test piece, and the test piece permeates and penetrates into the carrier gas. In the gas barrier test method using the gas barrier test apparatus that measures the permeability of the permeation target gas by measuring the permeation target gas,
A gas barrier test method comprising performing the gas barrier test by fixing the test piece in a curved state and applying stress to the test unit or the test cell. A gas barrier test jig for a test piece that can be set in a test unit or a test cell in a curved state of a test piece that is a film to be tested or a test sheet to form a container or various films,
The test piece has a flow path through which the carrier gas can flow in the main body, one side surface thereof is formed in a curved shape, a through hole is formed in the one side surface, and the through hole is covered. The test piece pressing block is provided with an inlet and a discharge port for the permeation test target gas, and further provided with a test piece pressing block having a space inside. A gas barrier test jig characterized in that a permeation target gas can be measured by circulating a permeation test target gas and measuring a carrier gas containing the permeation test target gas that has passed through the test piece.