JP5163893B2 - Gas permeation measuring device and gas permeation measuring method - Google Patents

Description

The present invention relates to a gas permeation amount measuring apparatus and a gas permeation amount measuring method for measuring a permeation amount of a specific type of gas that permeates from the inside to the outside of a plastic bottle.

Plastic bottles are widely used as containers for filling beverages and other liquids. For example, carbonated beverages containing carbon dioxide gas are filled. For plastic bottles filled with carbonated beverages, the amount of carbon dioxide permeation from the inside of the bottle to the outside should be kept small so that the refreshing feeling is not impaired by the permeation of carbon dioxide to the outside over time. Is required.

For this reason, it is necessary to confirm the permeability of carbon dioxide gas from a plastic bottle, and various gas permeation amount measuring methods have been put into practical use. For example, there is a bottle in which carbon dioxide gas is filled in a bottle having a pressure gauge in the mouth, and the amount of carbon dioxide permeated is measured from the pressure decrease measured by the pressure gauge (Patent Document 1, paragraph 0002).
JP-A-6-50874

However, in the gas permeation amount measuring method described above, it takes a long time (for example, several months) to measure the amount of pressure decrease to the extent that carbon dioxide permeability from a plastic bottle can be specified. This has limited the rapid development of new plastic bottles. In addition, since the measurement accuracy is insufficient with this measurement method, the reliability of the measurement result may be lowered. On the other hand, in order to increase the reliability of the measurement result, it is necessary to repeatedly perform measurement using a large number of samples, which may lead to a prolonged development period and an increase in development cost.

Therefore, the present invention provides a gas permeation amount measuring apparatus and a gas permeation amount measurement method capable of accurately measuring the permeation amount of a specific type of gas permeating from the inside to the outside of a plastic bottle in a short period of time. For the purpose.

In order to solve the above problems, the gas permeation amount measuring device of the present invention is a gas permeation amount measuring device that measures the permeation amount of a specific gas from the inside to the outside of a plastic bottle, and is filled with a specific gas. A chamber for containing a sealed plastic bottle in an airtight state, a temperature maintaining means for maintaining the inside of the chamber at a predetermined temperature, and a permeation amount for measuring a permeation amount of a specific gas from the inside to the outside of the plastic bottle. comprising a measuring means, while maintaining the inside of the chamber housing the plastic bottle in an airtight state, and measuring the transmission amount of a particular gas from the inside to the outside of the plastic bottles, transmission amount measurement means, infrared A light source unit that emits light, and a light amount detection unit that is disposed apart from the light source unit and detects the amount of incident infrared light, and the light source unit and the light amount detection unit are within the chamber. Located outside the plastic bottle, the light amount detection unit detects the amount of infrared light that has passed through the gas existing between the light source unit and the light amount detection unit, and the amount of infrared light is outside the chamber. is the sensed wherein Rukoto without removing the gas to.

In the gas permeation amount measuring apparatus of the present invention, a PET bottle can be used as the plastic bottle.

In the gas permeation amount measuring apparatus of the present invention, carbon dioxide gas can be selected as the specific gas.

In the gas permeation amount measuring apparatus of the present invention, it is preferable that the inside of the chamber is filled with air at the initial stage of airtightness.

In the gas permeation amount measuring apparatus of the present invention, the permeation amount measuring means can continuously measure the permeation amount of a specific gas.

In the gas permeation amount measuring apparatus according to the present invention, the temperature maintaining means is preferably a thermostatic chamber that houses a chamber therein.

The gas permeation amount measuring method of the present invention is a gas permeation amount measuring method for measuring the permeation amount of a specific gas from the inside of the plastic bottle to the outside, and is a gas for filling and sealing a specific gas in the plastic bottle. A filling and sealing step, a plastic bottle in which a specific gas is sealed in the gas filling and sealing step, and a bottle housing step in which the inside of the chamber is hermetically sealed; and a plastic bottle in the bottle housing step while maintaining the contained chamber airtight predetermined temperature, the transmission amount measuring means comprises a transmission amount measurement step of measuring the transmission amount of a particular gas from the inside to the outside of a plastic bottle, a transmission The quantity measuring means is disposed apart from the light source unit that emits infrared light, and detects the amount of incident infrared light. The light source unit and the light amount detection unit are disposed inside the chamber and outside the plastic bottle, and the light amount detection unit exists between the light source unit and the light amount detection unit. detecting the light quantity of the infrared light that has passed through the gas, the amount of infrared light is characterized Rukoto detected without removing the gas to the outside of the chamber.

According to the present invention, there are provided a gas permeation amount measuring apparatus and a gas permeation amount measurement method capable of accurately measuring a permeation amount of a specific type of gas permeating from the inside to the outside of a plastic bottle in a short period of time. be able to.

Hereinafter, a gas permeation amount measuring apparatus according to an embodiment of the present invention will be described in detail with reference to the drawings.
In this embodiment, a PET (polyethylene terephthalate) bottle is used as a plastic bottle, and carbon dioxide gas (CO ₂ ) is used as an example of a specific gas (gas) to be measured. However, the present invention is not limited to this, and the present invention can also be applied to plastic bottles of other materials and gases other than carbon dioxide.

FIG. 1 is a partial cross-sectional view showing a configuration of a gas permeation amount measuring apparatus 10 according to the present embodiment. In FIG. 1, the PET bottle 20, the cap 30, the chamber 40, and the constant temperature bath 50 are shown in cross section.

As shown in FIG. 1, the gas permeation amount measuring apparatus 10 includes a cap 30 as a lid member, a chamber 40, a thermostat 50, a circulator 52, and a gas permeation amount measurement sensor 60 as a permeation amount measuring unit. . In FIG. 1, the outer shape of the gas permeation amount measuring sensor 60 is simply shown.

The cap 30 is detachable from the mouth portion 21 of the PET bottle 20 accommodated in the chamber 40, and the PET bottle 20 is sealed by attaching the cap 30 after filling the PET bottle 20 with carbon dioxide gas. The cap 30 and the mouth portion 21 are fixed by, for example, forming a spiral groove that meshes with the cap 30 and the mouth portion 21 and tightening the cap 30 against the mouth portion 21 in the same manner as in an actual product. Good. The cap 30 is preferably made of metal from the viewpoint of suppressing the permeation of carbon dioxide gas from the cap 30, and can be made of aluminum, for example. On the other hand, a plastic cap used for an actual product can also be used, so that the permeation rate of carbon dioxide gas from the inside 20a of the PET bottle 20 to the outside 20b of the entire PET bottle 20 including the cap 30 can be used. Can be evaluated. Moreover, it can also measure in the state which has arrange | positioned the sealing agent between the cap 30 and the opening part 21. FIG. The PET bottle 20 can take a form other than the form using the cap 30 as long as it can be filled and sealed with carbon dioxide gas. For example, a PET or other thermoplastic resin film may be laminated on an aluminum foil and heat sealed at the mouth of the PET bottle, that is, heated to melt and seal the thermoplastic resin.

The chamber 40 includes a main body portion 41 on which the PET bottle 20 can be placed, and a lid portion 42 that is closely fixed to the upper portion of the main body portion 41. The chamber 40 can be hermetically sealed by placing the PET bottle 20 therein and fixing the lid 42 to the main body 41. As long as the chamber 40 has the material and weight which can be used in the thermostat 50, arbitrary things can be used. As a material of the thermostat 50, stainless steel, aluminum, glass, and plastic can be used, and among these, stainless steel can be preferably used. The fixing strength of the main body portion 41 and the lid portion 42 is a pressure higher than the atmospheric pressure in the chamber 40 in consideration of the flow of carbon dioxide gas from the PET bottle 20 into the atmosphere filled in the chamber 40. However, the airtight state can be maintained. The chamber 40 may be disposed so as to sink to the bottom surface in the thermostat 50 by its own weight, or may be fixed to the thermostat 50 using a fixing member (not shown).
As a specific example of the fixing method of the main body portion 41 and the lid portion 42, an O-ring or a gasket is sandwiched between the two and sealed by a clamp joint method, a bolt fastening method, a screw fitting method, or the like. Can be preferably used.

The thermostat 50 is a container filled with a temperature-controllable medium 51 (for example, water, oil, air). A circulator 52 is connected to the constant temperature bath 50. The circulator 52 circulates the medium 51 between the thermostat 50 and controls the temperature of the medium 51 in the thermostat 50 to a desired temperature by heating or cooling the medium 51. The chamber 40 is disposed in the medium 51, and the internal temperature is maintained at a predetermined temperature under the control of the circulator 52. Therefore, the thermostat 50 and the circulator 52 constitute a temperature maintaining means.

A gas permeation amount measurement sensor 60 is arranged in the lid portion 42 of the chamber 40 so as to penetrate vertically in a state where the airtight state in the chamber 40 can be maintained. The gas permeation amount measuring sensor 60 is disposed inside the chamber 40 and outside the PET bottle 20. The gas permeation amount measuring sensor 60 is connected to a data processing unit 70 disposed outside the chamber 40 via a conducting wire 71 extending from one end thereof.

The configuration of the gas permeation amount measurement sensor 60 will be described below with reference to FIG. FIG. 2 is a cross-sectional view showing a configuration of the gas permeation amount measurement sensor 60 according to the present embodiment. The gas permeation amount measuring sensor 60 includes a hollow cylindrical casing 61, and a light source 63, a filter 64, and a light amount detector 65 are disposed in an internal space 62 of the casing 61. Yes. The filter 64 and the light amount detection unit 65 are sequentially arranged in the traveling direction of the infrared light emitted from the light source unit 63.

The housing part 61 is formed with an opening 66 that allows gas to flow in and out between the outside of the housing part 61 and the internal space 62. When the gas permeation amount measuring sensor 60 provided with the opening 66 is arranged outside the PET bottle 20 and inside the chamber 40, the gas existing in this space is introduced into the internal space 62 of the gas permeation amount measuring sensor 60. can do. For this reason, if carbon dioxide gas permeates into the chamber 40 from the inside of the PET bottle 20, the interior space 62 is also filled with the gas containing the permeated carbon dioxide gas. The shape of the opening 66 may be a net shape, a lattice shape, or a window shape.

The gas permeation amount measuring sensor 60 is attached to the lid portion 42 of the chamber 40 so that the airtight state in the chamber 40 can be maintained. Specifically, the housing part 61 is fixed so that a gap through which gas can pass is not formed between the housing part 61 and the lid part 42. At this time, the entire opening 66 is disposed in the sealed space of the chamber 40. For this reason, even if the gas permeation amount measuring sensor 60 protrudes upward from the lid portion 42 of the chamber 40, the inside of the chamber 40 and the gas permeation amount measuring sensor 60 communicate with each other to measure the gas in the chamber 40. It can be introduced into the sensor 60 and the airtight state inside the chamber 40 is maintained. Therefore, the inside of the gas transmission amount measurement sensor 60 constitutes a part of the chamber 40. The gas permeation amount measuring sensor 60 may be attached to the lid portion 42 in any form as long as the gas permeation amount measuring sensor 60 is attached so as not to generate a gap through which gas can pass, but with an adhesive such as an epoxy resin. It is preferable to seal the clearance between the two using a means such as a seal or a seal through an O-ring.

Any light source unit 63 can be used as long as it can emit infrared light including a wavelength (for example, around 4.3 μm) absorbed by carbon dioxide gas toward the filter 64 and the light amount detection unit 65. The light amount detector 65 is a sensor that detects the amount of incident infrared light, and may be any device that can detect the amount of infrared light having a wavelength absorbed by carbon dioxide. The filter 64 is an optical filter that transmits at least a wavelength absorbed by carbon dioxide. When such a filter 64 is used, it is possible to accurately detect a change in the amount of infrared light having a wavelength absorbed by carbon dioxide. Since the change in the amount of light changes in accordance with the concentration of carbon dioxide, the concentration of carbon dioxide can be known from the amount of light detected by the light amount detector 65, thereby transmitting the carbon dioxide that has passed through the PET bottle 20 into the chamber 40. The amount can be measured accurately.

As the gas permeation amount measurement sensor 60, for example, a CO ₂ conversion module (GMM220 series) manufactured by Vaisala Co., Ltd., or a carbon dioxide gas sensor (SSA100) manufactured by SSC Co., Ltd. can be used.

When measuring the amount of carbon dioxide gas that permeates the PET bottle 20 as in the gas permeation amount measuring apparatus 10 according to the present embodiment, the main body portion is filled with atmospheric air (atmosphere) in the chamber 40. The lid portion 42 is fixed to 41 to make the chamber 40 airtight. That is, the inside of the chamber 40 is filled with air in the initial stage of airtightness. Depending on the type of gas to be measured, the measurement accuracy can be increased by evacuating the chamber 40 or filling it with a gas of a predetermined component.

Although not shown in FIG. 2, as a power source for driving the light source unit 63 and the light amount detection unit 65, for example, a battery built in the housing unit 61 or a lead wire is connected. Use an external power supply. In the case of using the built-in battery, it is preferable to provide a switch arranged on the outer surface of the casing 61 and outside the chamber 40, and to select the on / off at a desired timing because the airtight state in the chamber 40 can be maintained. .

The light quantity data detected by the light quantity detection unit 65 is sent to the data processing unit 70 via the conductor 71. The data processing unit 70 calculates the amount of carbon dioxide permeation from the input light quantity data. The calculation of the transmission amount is performed using a conversion table of the light amount and the transmission amount stored in the data processing unit 70 in advance. More specifically, the conversion from the gas concentration in the chamber to the permeation amount is based on the gas concentration measurement result in the chamber 40 measured by the gas permeation amount measurement sensor 60 and the initial gas concentration in the chamber measured in advance. Is subtracted and then the subtraction result is multiplied by the internal volume of the chamber 40. As the data processing unit 70, for example, a personal computer, a printing device that can output data in a predetermined format, or a storage device that stores data in a predetermined area can be used.

Furthermore, in the gas permeation amount measuring apparatus 10, the permeation speed can be converted from the permeation amount of carbon dioxide gas. Conversion from the permeation amount to the permeation speed is performed by calculating an increase in the concentration of carbon gas between two time points selected from the measurement time and dividing by a predetermined time (for example, one day). Therefore, the gas permeation amount measuring sensor 60 as a gas concentration measuring means for measuring the carbon dioxide concentration in the chamber 40, and the permeation amount (permeation speed) of the carbon dioxide gas from the gas concentration measured by the gas permeation amount measuring sensor 60. A transmission amount measuring unit can be configured by the data processing unit 70 as the transmission amount calculating unit to calculate.

A procedure for measuring the permeation amount of carbon dioxide using the gas permeation amount measuring apparatus 10 having the above configuration will be described.

First, carbon dioxide gas is filled in the PET bottle 20, and the cap 30 is fastened and fixed to the mouth portion 21 to seal the carbon dioxide gas in the PET bottle 20 (gas filling sealing step). Depending on the carbon dioxide content in the beverage filled in the PET bottle 20 as a product and other conditions, the carbon dioxide gas remains in a gaseous state or is dissolved in a liquid, and a predetermined amount is added to the PET bottle 20. Fill. In the case where carbon dioxide gas is dissolved in a liquid such as water, it is preferable that the carbon dioxide gas is dissolved after being dissolved at a low temperature or under pressure. The gas volume is a value obtained by dividing the volume of carbon dioxide dissolved in the liquid by the volume (capacity) of the liquid in the standard state (1 atmosphere 15.6 ° C.). When promoting the evaluation, it is preferable to increase the gas volume in the PET bottle 20.

Next, after the PET bottle 20 filled with carbon dioxide gas in the gas filling and sealing step is accommodated in the chamber 40, the lid portion 42 is fixed to the main body portion 41 to make the inside of the chamber 40 airtight (bottle accommodating step). ). In this bottle storing step, the lid 42 is fixed to the main body 41 while maintaining atmospheric pressure without filling the chamber 40 with gas or degassing the chamber 40. Thereby, the inside of the chamber 40 is filled with the same atmosphere as the outside of the chamber 40. A gas permeation measurement sensor 60 is fixed to the lid 42 in advance, and a lead 71 extending from the gas permeation measurement sensor 60 is connected to the data processing unit 70.

On the other hand, the constant temperature bath 50 is filled with the medium 51, and by operating the circulator 52, the medium 51 is set to a desired temperature in advance. The chamber 40 in which the PET bottle 20 is accommodated in the bottle accommodating step described above is submerged in the medium 51 and disposed at a predetermined position. In this state, the light source unit 63 and the light amount detection unit 65 are activated to start the measurement of the carbon dioxide gas transmission amount (transmission amount measurement step). During the measurement, the fixed state of the main body portion 41 and the lid portion 42 is maintained at a constant temperature, and the airtight state in the chamber 40 is maintained. Therefore, the carbon dioxide gas flowing out from the inside 20a of the PET bottle 20 to the outside 20b can be kept in the chamber 40, and the gas existing inside the chamber 40 and outside the PET bottle 20 is emitted from the light source unit 63. By detecting the amount of absorption of infrared light using the light amount detector 65, the amount of carbon dioxide permeation can be detected. Further, in the configuration of the gas permeation amount measuring apparatus 10, it is not necessary to take out the gas in the chamber 40 to be measured to the outside, so that the permeation amount of carbon dioxide gas can be measured continuously and accurately.

An example using the gas permeation amount measuring apparatus 10 according to the above embodiment will be described with reference to FIG. FIG. 3 is a graph showing changes in the permeation rate of carbon dioxide gas from a PET bottle in Example 1 and Example 2. In FIG. 3, the horizontal axis represents the elapsed time from the start of measurement (unit: time), and the vertical axis represents the permeation rate of carbon dioxide gas from the inside of the PET bottle to the outside (unit: cc / bottle / day).

<Example 1>
A preform (PF) having a weight of 31 g was prepared by a conventional injection molding method using polyethylene terephthalate (PET) resin, and then an average side wall thickness of 0.43 mm, a weight of 31 g, a bottle by biaxial stretch blow molding by a conventional method. A PET bottle having a height of 220 mm and a capacity of 500 ml was produced.

The obtained PET bottle was filled with carbonated water in which carbon dioxide gas was dissolved under a pressure of 5 ° C., and sealed with an aluminum cap. The gas volume in the filled PET bottle was 4.0. The obtained filled PET bottle is accommodated in a stainless steel chamber 40, and a stainless steel lid portion 40 to which a CO ₂ conversion module GMM222 manufactured by Vaisala Co., Ltd. is attached is used as a gas permeation amount measurement sensor 60. The chamber body 41 and the clamp joint were hermetically fixed.

The temperature of the chamber under measurement was maintained at 23 ° C. by using a thermostatic bath as the temperature maintaining means of the chamber 40, using water as the medium, and controlling the water temperature with a circulator. The signal from the gas permeation amount measuring sensor 60 was subjected to data processing using a data processing unit 70 in a personal computer, and the graph of FIG. The carbon dioxide gas permeation rate in the graph is calculated by calculating the amount of increase in concentration over the current 4 hours from the carbon dioxide concentration measured at 2 hours before and after the plot time and converting it to the permeation rate per day (24 hours). It is. The obtained results are indicated by black square marks (■) in FIG.

<Example 2>
The relationship between the carbon dioxide gas permeation rate and the elapsed time was determined in the same manner as in Example 1 except that the PET bottle had an average side wall thickness of 0.29 mm, a weight of 24 g, a bottle height of 220 mm, and a capacity of 500 ml. The obtained results are indicated by black triangle marks (▲) in FIG.

As shown in FIG. 3, in Example 2, after about 96 hours (about 4 days) have elapsed from the start of measurement, the carbon dioxide permeation rate (the amount of carbon dioxide permeation per day) becomes a substantially stable value. It is preferable to evaluate the permeability (total gas permeation amount in long-term storage) of carbon dioxide gas from a PET bottle in a range where the permeation rate is stable. Therefore, after about 96 hours have elapsed from the start of measurement, the carbon dioxide transmission rate can be measured with high accuracy. In addition, since the carbon dioxide permeation rate can be evaluated on the fifth day from the start of the measurement, the measurement period that conventionally required several months can be greatly shortened.

Similar to Example 2, in Example 1, the carbon dioxide permeation rate (the amount of carbon dioxide permeation per day) becomes a substantially stable value after about 144 hours (about 6 days) have passed since the start of measurement. Therefore, after about 144 hours have elapsed from the start of measurement, the carbon dioxide gas transmission rate can be measured with high accuracy. Further, since the carbon dioxide permeation rate can be evaluated on the seventh day from the start of the measurement, the measurement period which conventionally required several months can be greatly shortened.

With the configuration described above, the following effects are achieved according to the above embodiment.
(1) The measurement of the permeation rate of a specific gas from the inside of the plastic bottle to the outside can be performed in a short period of time.
(2) The permeation rate of a specific gas from the inside to the outside of the plastic bottle can be measured with high accuracy.
(3) Since it is not necessary to take out a specific gas from the inside of the chamber to the outside, a mechanism for taking out the gas and adjusting the pressure in the chamber becomes unnecessary. Therefore, it is possible to realize an apparatus that can maintain the temperature and pressure in the chamber at desired values while being simple.
(4) Since it is not necessary to take out a specific gas from the inside of the chamber to the outside, the permeation rate of the specific gas from the inside of the plastic bottle to the outside can be continuously measured.
(5) Promotional evaluation can be performed by making the pressure (internal pressure) of a specific gas in a plastic bottle at the time of sealing higher than the pressure of the specific gas in the atmosphere. Can evaluate the permeation rate of a specific gas.

A modification will be described below.
The gas permeation amount measuring sensor 60 may be disposed so as to penetrate the side wall of the main body 41 instead of the lid 42.

It is also possible to dispose all the casing portion 61 in the chamber 40 and allow the lead wire 71 to penetrate the main body portion 41 or the lid portion 42. In this case, the gas permeation amount measuring sensor 60 may be disposed at any position within the chamber 40 and outside the PET bottle 20 as long as ventilation in the opening 66 is secured.

In the gas permeation amount measurement sensor 60 described above, the light source unit 63, the filter 64, and the light amount detection unit 65 are housed inside, but the gas permeation amount measurement sensor may have other forms. For example, the light source unit, the filter, and the light amount detection unit can be arranged independently of each other. Moreover, while integrating the filter and the light amount detection unit, the light source unit may be arranged independently of the housing unit.

The arrangement of the light source unit and the light amount detection unit may be any form in which a gas containing a specific gas exists between them. Therefore, in addition to the above-described embodiment, for example, after the infrared light emitted from the light source unit is reflected by the reflecting mirror, it can be arranged to pass through the filter and enter the light amount detection unit. In this case, the reflecting mirror can take, for example, a form that is bonded and fixed to the inner wall of the chamber or a form that is formed by vapor deposition on the inner wall.

Further, one of the light source unit and the light amount detection unit may be disposed in the plastic bottle, and the other may be disposed outside the plastic bottle and inside the chamber.

The specific gas is not limited to carbon dioxide. For example, oxygen can be used as a specific gas. In this case, in order to improve measurement accuracy, it is preferable to start measurement after evacuating the chamber.

As the permeation amount measuring means for measuring the permeation amount of a specific gas, for example, a solid electrolyte type sensor can be used in addition to the gas permeation amount measurement sensor including a combination of the light source, the filter, and the light amount detection unit. For example, a CO ₂ monitor (MA series) manufactured by Chino Corporation can be suitably used.

Although the present invention has been described with reference to the above embodiment, the present invention is not limited to the above embodiment, and can be improved or changed within the scope of the purpose of the improvement or the idea of the present invention.

As described above, the gas permeation amount measuring apparatus according to the present invention is useful for a plastic bottle filled with a beverage containing gas.

It is a partial sectional view showing the composition of the gas permeation amount measuring device concerning the embodiment of the present invention. It is sectional drawing which shows the structure of the gas permeation | transmission amount measuring sensor which concerns on embodiment of this invention. It is a graph which shows the change of the permeation | transmission rate of the carbon dioxide gas from the PET bottle in Example 1 and Example 2. FIG.

Explanation of symbols

10 Gas permeation measuring device 20 PET bottle (plastic bottle)
20a inside 20b outside 21 mouth 30 cap (lid member)
40 Chamber 41 Body 42 Lid 50 Constant temperature bath (temperature maintaining means)
52 Circulator (Temperature maintenance means)
60 Gas permeation measuring sensor (permeation measuring means)
61 Housing 62 Internal space 63 Light source 64 Filter 65 Light quantity detector 66 Opening 70 Data processor

Claims (7)

A gas permeation measuring device for measuring a permeation amount of a specific gas from the inside to the outside of a plastic bottle,
A chamber for containing the plastic bottle filled and sealed with the specific gas in an airtight state;
Temperature maintaining means for maintaining the interior of the chamber at a predetermined temperature;
A permeation amount measuring means for measuring a permeation amount of the specific gas from the inside to the outside of the plastic bottle;
With
While maintaining the inside of the chamber containing the plastic bottle in an airtight state, measure the permeation amount of the specific gas from the inside of the plastic bottle to the outside ,
The transmission amount measuring means includes a light source unit that emits infrared light, and a light amount detection unit that is arranged apart from the light source unit and detects the amount of incident infrared light,
The light source unit and the light amount detection unit are arranged inside the chamber and outside the plastic bottle,
The light amount detection unit detects the amount of infrared light that has passed through the gas existing between the light source unit and the light amount detection unit,
Gas permeation amount measuring device according to claim Rukoto detected without the light amount of the infrared light taking out the gas to the outside of the chamber. The gas permeation amount measuring apparatus according to claim 1, wherein the plastic bottle is a PET bottle. The gas permeation amount measuring apparatus according to claim 1, wherein the specific gas is carbon dioxide gas. The gas permeation amount measuring apparatus according to any one of claims 1 to 3, wherein the inside of the chamber is filled with air at an initial stage of airtightness. The gas permeation amount measuring device according to any one of claims 1 to 4, wherein the permeation amount measurement unit continuously measures the permeation amount of the specific gas. The gas permeation amount measuring apparatus according to any one of claims 1 to 5, wherein the temperature maintaining means is a thermostatic chamber that houses the chamber therein. A gas permeation measuring method for measuring a permeation amount of a specific gas from the inside to the outside of a plastic bottle,
A gas filling and sealing step of filling and sealing the specific gas in the plastic bottle;
A bottle housing step in which the plastic bottle in which the specific gas is sealed in the gas filling and sealing step is housed in a chamber, and the inside of the chamber is airtight;
While maintaining the inside of the chamber in which the plastic bottle is accommodated in the bottle accommodating step in an airtight state at a predetermined temperature, the permeation amount measuring means allows the specific gas to flow from the inside to the outside of the plastic bottle. A transmission amount measuring step for measuring the transmission amount;
With
The transmission amount measuring means includes a light source unit that emits infrared light, and a light amount detection unit that is arranged apart from the light source unit and detects the amount of incident infrared light,
The light source unit and the light amount detection unit are disposed inside the chamber and outside the plastic bottle, and the light amount detection unit is configured to remove gas existing between the light source unit and the light amount detection unit. Detect the amount of infrared light that has passed,
The gas permeation amount measuring method, wherein the light quantity of the infrared light is detected without taking out the gas to the outside of the chamber .