JP6352577B1 - Package - Google Patents

Abstract

The packaging body 1 according to the present invention includes a first storage region portion 11 and a second storage region portion 12 that store a plurality of substances, a material that can flow and the first storage region portion 11 and the second storage region portion 12. Are connected to each other. And the 1st storage area part 11 and the 2nd storage area part 12 are comprised so that it may reduce / enlarge according to the pressure from the outside, and the reduction | decrease of the said 1st storage area part 11 and the 2nd storage area part 12 / The substance is configured to flow through the communication passages 21 and 22 in accordance with the expansion. Furthermore, the communication path is configured to make the gas into microbubbles in the liquid when the substance flows. Furthermore, a discharge passage that communicates with at least one internal space of the first storage region portion and the second storage region portion and has a discharge port that discharges a substance from the internal space is provided.

Description

  The present invention relates to a package, and particularly relates to a package capable of mixing contained substances.

  Nanobubbles are nano-sized (for example, a particle size of 1000 nm or less) microbubbles present in a solvent such as water, and have properties that are significantly different from ordinary bubbles. For example, nanobubbles are expected to have excellent effects on the human body, such as growth promotion effects, antioxidant effects, and bactericidal effects.

  And it has also been studied to contain nanobubbles in various solvents using the above-mentioned properties of nanobubbles. For example, nanobubbles can be taken into the human body by containing nanobubbles in a solvent that forms a cosmetic liquid, a cleaning agent, a medicine, a beverage, or the like.

Japanese Patent Laid-Open No. 2006-120919

  On the other hand, since nanobubbles are present as microbubbles in the solvent, the amount dissolved in the solvent can decrease with time. For this reason, for example, even when the purpose is to incorporate nanobubbles into the body, there is a problem in that it is difficult to efficiently incorporate nanobubbles due to a short dissolution period in the solvent and a decrease in the dissolved amount. .

  Here, Patent Document 1 discloses a packaging bag for stably holding a liquid containing a certain component. This packaging bag has an aluminum layer, and is configured so that a liquid containing a certain component can be stored for a long period of time while ensuring light shielding properties, moisture shielding properties, and gas barrier properties.

  However, even in the packaging bag as described above, the nanobubbles can be reduced if the nanobubbles are contained in the solvent. That is, it is difficult to stably maintain the mixed state of the liquid and gas mixture. For this reason, there arises a problem that it is difficult to obtain a solvent having a large amount of dissolved nanobubbles as necessary.

  Moreover, not only nanobubbles but also a case where a mixture of a plurality of substances is contained in the packaging bag described above, it may be difficult to stably maintain the mixed state of the mixture. For this reason, the problem that it is difficult to obtain the mixture which maintained the mixed state as needed arises.

  Furthermore, when the mixture maintained in the mixed state is discharged from the packaging bag, it becomes difficult to maintain the mixed state. Then, if you open the packaging bag and take out the mixture at once, the mixed state is maintained for the amount of mixture that is used immediately, but the mixed state is maintained for the amount of mixture that is not used immediately. Can not. For this reason, it is necessary to discharge | emit appropriate amount from a packaging bag according to the use of a mixture.

  As described above, the object of the present invention is to provide a package that can solve the above-described problem that it is difficult to obtain an appropriate amount of a mixture of a plurality of substances while maintaining a desired mixed state. It is to provide.

The package which is one form of the present invention,
A first storage region portion and a second storage region portion having an internal space for storing a plurality of substances;
The substance is circulated, and includes a communication path that allows the internal space of the first storage region portion and the internal space of the second storage region portion to communicate with each other.
The first storage region portion and the second storage region portion are configured such that the internal space is reduced / expanded according to an external pressure, and the internal spaces of the first storage region portion and the second storage region portion are reduced. / The substance is configured to flow through the communication path in response to expansion,
At least one of the substances is a gas, and at least the other one is a liquid capable of containing gas bubbles,
The communication path is configured to microbubble the gas in the liquid when the substance flows.
Furthermore, a discharge passage communicating with at least one internal space of the first storage region portion and the second storage region portion, and having a discharge port for discharging the substance from the internal space,
The discharge passage of the discharge passage is configured to be changeable from a closed state to an open state.
The configuration is as follows.

  According to the above configuration, first, when a pressure is applied by pressing the first storage region portion from the outside, the internal space of the first storage region portion is reduced, and the substance stored in the internal space of the first storage region portion is reduced. It distribute | circulates to the internal space of a 2nd accommodation area | region part via a communicating path, and the internal space of the said 2nd accommodation area | region expands according to this. Thereafter, when pressure is applied by pressing the second storage region portion from the outside, the internal space of the second storage region portion shrinks, and the substance stored in the internal space of the second storage region portion passes through the communication path. It distribute | circulates to the internal space of a 1st accommodating area | region part, and the internal space of the said 1st accommodating area | region expands according to this. By repeatedly performing such an operation, a plurality of substances flowing between the first storage area and the second storage area through the communication path are mixed, and a mixture is generated in the package. Can do. As a result, such a mixture can be obtained immediately after mixing. In particular, when the substances to be contained are liquid and gas, the liquid and gas are mixed, and the gas is microbubbled in the liquid when passing through the communication path. Thereby, a liquid containing microbubbles can be obtained.

  Furthermore, it comprises at least one discharge passage of the first storage region portion and the second storage region portion, and the discharge port of the discharge passage is changed from a closed state to an open state, according to the application. An appropriate amount of the mixture can be discharged while the mixed state is maintained.

  In addition, the said package takes the structure that the convex part was provided in the inner wall face of the said communicating path. Further, the packaging body has a configuration in which a hole forming member having a plurality of holes through which the substance can flow is provided in the communication path. Moreover, in the said package, the some hole formed in the said hole formation member provided in the said communicating path is formed in the clearance gap between the some polygonal shape object arrange | positioned in the said communicating path, The configuration is as follows. Thereby, gas can be made into microbubbles efficiently in a liquid.

In the package,
A plurality of the discharge passages;
By opening the discharge ports of any one or a plurality of the discharge passages, the discharge amount of the substance from the discharge passages can be changed to a plurality of different states.

In the package,
It is possible to change the state where the discharge port of the discharge passage is opened by cutting the outer periphery formation portion from the state where the discharge port of the discharge passage is blocked by the outer periphery formation portion of the member forming the package itself. It is configured so that
By cutting the outer periphery forming portion at different cutting points, the discharge amount of the substance from the discharge passage can be changed into a plurality of different states.

In the package,
A plurality of the discharge passages;
It is configured to be able to change from a state in which all the discharge ports of the plurality of discharge passages are closed to a plurality of states in which the numerical apertures of the discharge ports are different.

In the package,
It is possible to change the state where the discharge port of the discharge passage is opened by cutting the outer periphery formation portion from the state where the discharge port of the discharge passage is blocked by the outer periphery formation portion of the member forming the package itself. It is configured so that
By cutting the said outer periphery formation part in a different cutting location, it is comprised so that the numerical aperture of the said discharge port can be changed into several different states.

In the package,
One discharge passage which is a predetermined number of the discharge passages communicating with the internal space of the first storage region portion and the other discharge passage which is a predetermined number of the discharge passages communicating with the internal space of the second storage region portion And comprising
The number of the discharge passages is different between the one discharge passage and the other discharge passage,
The cutting location for cutting the outer periphery forming portion so that the one discharge passage is opened is different from the cutting location for cutting the outer periphery forming portion so that the other discharge passage is opened.
The configuration is as follows.

In the package,
A plurality of the discharge passages communicating with at least one internal space of the first storage region portion and the second storage region portion;
At least one of the plurality of discharge passages is formed longer than the other,
By cutting the outer periphery forming portion at the first cutting location, at least one of the plurality of discharging passages is opened longer than the other, and the second cutting location is different from the first cutting location. The plurality of discharge passages are all opened by cutting the outer periphery forming portion.

In the package,
For each different cut location, a notch that defines the cut position of the cut location is formed on the outer edge of the package,
The configuration is as follows.

In the package,
A part of two flexible sheet bodies are bonded together,
Between the two sheet bodies, an internal space of the first storage region portion, an internal space of the second storage region portion, the communication passage, and the discharge passage are formed,
The discharge port of the discharge passage is in a state of being blocked by bonding the two sheet bodies,
The discharge port of the discharge passage is opened by cutting the outer periphery forming portion formed around the first storage region portion and / or the second storage region portion by bonding the two sheet bodies. It is configured.

  By the said structure, it can change to the several state from which the numerical aperture of a discharge passage and the discharge | emission amount of a substance differ by cutting a package body in a different cutting location. Thereby, it is possible to discharge an appropriate amount of the mixture according to the application while maintaining the mixed state by a simple operation.

In the package,
A plurality of the communication passages are provided between the first accommodation area and the second accommodation area.
The configuration is as follows.

In the package,
At least one of the communication passages is configured to circulate a substance from the internal space of the first storage region portion to the internal space of the second storage region portion, and at least the other one is the second storage region portion. The material is configured to circulate from the internal space to the internal space of the first storage region portion.
The configuration is as follows.

In the package,
Among the communication passages, at least one of the communication passages is configured such that the width of the passage becomes narrower from the internal space of the first storage region portion toward the internal space of the second storage region portion, and at least the other one is described. It is configured such that the width of the passage is narrowed from the internal space of the two storage region portions toward the internal space of the first storage region portion,
The configuration is as follows.

  According to the said structure, the quantity of the substance distribute | circulated between a 1st accommodating area | region part and a 2nd accommodating area | region part can be increased by providing multiple communicating paths. In addition, by setting the direction in which the substance in the communication path flows, the substance can be efficiently circulated and mixed. As a result, a mixture can be obtained efficiently.

In the package,
One or more other storage area portions having an internal space for storing the substance,
The storage area is communicated with the internal space of the first storage area and / or the internal space of the second storage area via a communication path.
The configuration is as follows.

  According to the said structure, a different substance can be beforehand accommodated in each area | region part by providing more accommodation area | region parts. Then, by pressing one of the region portions from the outside and applying pressure, each substance is mixed as described above. Thereby, the mixture which mixed many kinds of substances can be obtained in a mixed state.

Moreover, the package which is the other form of this invention,
A first storage area, a second storage area and a third storage area having an internal space for storing a plurality of substances;
The substance is circulated, and a first series passage that allows the internal space of the first storage region portion and the internal space of the third storage region portion to communicate with each other; the internal space of the second storage region portion; A second communication passage that communicates with the internal space of the third storage region portion, and
The first storage region portion and the second storage region portion are configured such that the internal space is reduced / expanded according to pressure from the outside, and the internal space of the first storage region portion and the second storage region portion The material is configured to flow through the first series passage and the second communication passage in response to reduction / expansion of
The configuration is as follows.

And in the above package,
When at least one of the substances is a gas and at least the other is a liquid capable of containing gas bubbles,
The first series passage and the second communication passage are configured to make a gas into microbubbles in the liquid when the substance flows.
The configuration is as follows.

  Even in the package having the above-described configuration, the substance flows between the first accommodation area and the second accommodation area through the third accommodation area through the communication path. A liquid containing bubbles can be generated.

Moreover, the substance mixing and discharging method according to another aspect of the present invention includes:
At least one is a gas, and at least one other is a liquid that can contain gas bubbles. By pressing and alternately reducing / enlarging the internal space of the first storage area and the internal space of the second storage area, the internal space of the first storage area and the second storage area By causing the substance to flow through a communication path that communicates with the internal space of the gas, the gas is microbubbled in the liquid in the communication path,
A state in which the discharge port of the discharge passage communicating with at least one internal space of the first storage region portion and the second storage region portion and having a discharge port for discharging the substance from the internal space is blocked. Change from open to open,
The configuration is as follows.

And in the above substance mixing and discharging method,
From a state in which all the discharge ports of the plurality of discharge passages are blocked, the numerical aperture of the discharge port or the discharge amount of the substance from the discharge passage is changed to a plurality of different states.
The configuration is as follows.

Moreover, in the above-mentioned substance mixing and discharging method,
By cutting the outer periphery forming portion from the state where the discharge port of the discharge passage is blocked by the outer periphery forming portion of the member forming the package itself, the discharge passage of the discharge passage is changed to the opened state. Along with cutting the outer periphery forming portion at different cutting locations, the numerical aperture of the discharge port or the discharge amount of the substance from the discharge passage is changed to a plurality of different states.
The configuration is as follows.

  Even in the substance mixing and discharging method, the substance flows through the communication path between the first containing area part and the second containing area part, so that a liquid containing a mixture of a plurality of substances and microbubbles is generated. be able to. And by changing from the state where the discharge port of the discharge passage was closed to the opened state, it is possible to discharge an appropriate amount of the mixture according to the application while maintaining the mixed state.

  By being configured as described above, the present invention can obtain an appropriate amount of a mixture of a plurality of substances while maintaining a desired mixed state.

It is a figure which shows the structure of the package in the 1st Embodiment of this invention. It is a figure which shows the mode at the time of utilization of the package disclosed in FIG. It is a figure which shows the mode at the time of utilization of the package disclosed in FIG. It is a figure which shows the structural example of the communicating path of the package disclosed in FIG. It is a figure which shows the mode at the time of utilization of the package disclosed in FIG. It is a figure which shows the modification of the package which is this invention. It is a figure which shows the mode at the time of utilization of the package disclosed in FIG. It is a figure which shows the mode at the time of utilization of the package disclosed in FIG. It is a figure which shows the modification of the package which is this invention. It is a figure which shows the modification of the package which is this invention. It is a figure which shows the modification of the package which is this invention. It is a figure which shows the modification of the package which is this invention. It is a figure which shows the modification of the package which is this invention.

<Embodiment 1>
A first embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a diagram illustrating a configuration of a package, and FIGS. 2 to 3 are diagrams illustrating a state when the package is used. FIG. 4 is a diagram illustrating a configuration example of a communication path constituting the package.

  In FIG. 1, an example of a structure of the package 1 in this embodiment is shown. Fig.1 (a) is a top view of the package 1, and FIG.1 (b) is the packaging cut in the arbitrary positions (position in which the communicating path 21 is formed) of the up-down direction of Fig.1 (a). 1 is a cross-sectional view of a body 1.

  The packaging body 1 in the present embodiment is configured such that a part is bonded together in a state where two sheet bodies are laminated. The sheet body may be made of any material such as polyethylene or aluminum.

  Specifically, the packaging body 1 includes two housing regions 11 and 12, two communication passages 21 and 22, each having an outer shape indicated by a dotted line in FIG. The other portions are bonded to each other so as to form a space constituting the discharge passages 31 and 32. That is, as shown in the cross-sectional view of FIG. 1B, the package body 1 includes two stacked sheet bodies, two storage area portions 11 and 12, two communication paths 21 and 22, and a plurality of sheets. Only the portions constituting the discharge passages 31 and 32 are not attached to each other, and the other portions are attached to each other. In addition, although the location where two sheet bodies are mutually bonded is thermobonded by the thermocompression-bonding sealer, for example, it may be bonded by any method.

  The two storage area portions 11 and 12 include a first storage area portion 11 and a second storage area portion 12. Liquid and gas are accommodated in the internal spaces of the accommodating region portions 11 and 12. For example, the liquid is a cosmetic liquid and the gas is hydrogen gas. Here, liquid and gas may be initially stored separately, such as cosmetic liquid in the internal space of the first storage region 11 and hydrogen gas in the internal space of the second storage region 12. Or it may be accommodated in each accommodation field part 11 and 12 in the state where liquid and gas were mixed. In addition, although the liquid and gas are mentioned as an example as a substance accommodated in the internal space of each accommodating area | region part 11 and 12, different types of liquids and gases may be sufficient, sol and gel, Furthermore, A solid such as a powder may be used. These substances are fluid substances that can flow through the communication passages 21 and 22, as will be described later.

  The two communication passages 21 and 22 are passages that allow the internal space of the first storage region portion 11 and the internal space of the second storage region portion 12 to communicate with each other. For this reason, the communication passages 21 and 22 can circulate so that the plurality of substances accommodated in the respective accommodating area portions 11 and 12 can pass between the accommodating area portions 11 and 12. However, the communication passages 21 and 22 are configured to define the flow direction of the substance. For example, the communication passage 22 is configured such that the width of the passage becomes narrower from the internal space of the first storage region portion 11 toward the internal space of the second storage region portion 12. For this reason, the communication path 22 functions as a valve, and is configured such that the substance flows from the first storage region portion 11 toward the second storage region portion 12. On the other hand, the communication passage 21 is configured such that the width of the passage becomes narrower from the internal space of the second storage region portion 12 toward the internal space of the first storage region portion 11. For this reason, the communication path 21 functions as a valve, and is configured such that the substance flows from the second storage region portion 12 toward the first storage region portion 11. However, the flow direction of the communication paths 21 and 22 may not necessarily be defined.

  Here, since the internal space of the first storage region portion 11 and the second storage region portion 12 described above is a space formed between two flexible sheet bodies, it is subjected to pressure from the outside. Accordingly, the internal space itself is configured to be reduced or enlarged. For example, as shown by the arrow in FIG. 2B, when the first accommodating region 11 is pushed from the outside and pressure is applied, the internal space of the first accommodating region 11 is reduced. Then, as shown by the arrow in FIG. 2 (a), the substance in the first storage region portion 11 flows through the communication path 22 and flows into the second storage region portion 12, and accordingly, The internal space of the second storage area 12 is enlarged. Thereafter, as shown by the arrow in FIG. 3B, when the second housing region 12 is pushed from the outside and pressure is applied, the internal space of the second housing region 12 is reduced. Then, as shown by the arrow in FIG. 3 (b), the substance accommodated in the second accommodating region 12 flows into the first accommodating region 11 through the communication path 21, and accordingly, The internal space of the first storage area 11 is enlarged.

  At this time, each of the communication paths 21 and 22 described above is configured to make the gas in the liquid into microbubbles when the substance flows. For example, the communication passages 21 and 22 are formed so that the width of the passage is extremely small at the inflow portion to the accommodation region portion on the downstream side, so that when the substance in which the liquid and the gas are mixed flows, the gas in the liquid flows. Microbubbles will be formed.

  Further, the communication paths 21 and 22 may be configured as shown in FIG. For example, as shown to Fig.4 (a), the convex part 21a may be provided in the inner wall face of the communicating path 21. FIG. As described above, the substance in which the liquid and the gas are mixed flows through the communication path 21 provided with the convex portion 21a, so that the gas in the liquid becomes microbubbles. Here, it is desirable that the generated microbubbles have a nano size with a particle size of 1000 nm or less, for example. The communication path 22 has the same configuration.

  Further, for example, as shown by a shaded portion in FIG. 4B, the communication passage 21 may be filled with a porous body 21b (hole forming member). The porous body 21b is made of, for example, a cotton-like fiber material and has a large number of holes. When the substance in which the liquid and the gas are mixed passes through the numerous holes, the gas in the liquid becomes microbubbles. In addition, as for the magnitude | size of a hole, it is desirable that a diameter is 1 mm or less. In addition, a large number of holes may be formed by gaps between these polygonal shaped objects, such as a honeycomb structure as described later. Good. By doing in this way, the further bubble size miniaturization can be performed efficiently.

  In the above configuration, as shown in FIG. 2 and FIG. 3, by alternately pressing externally against the first storage region portion 11 and the second storage region portion 12, the inside of the first storage region portion 11. The space and the internal space of the second storage area portion 12 are alternately reduced / enlarged. Then, the mixture of the liquid and gas accommodated in the internal space of the first storage region portion 11 and the internal space of the second storage region portion 12 repeats circulation in the communication paths 21 and 22, and the communication path 21. , 22 is a mixture of liquid and gas, and the gas is microbubbled in the liquid. As a result, a liquid containing microbubbled gas can be generated, and such a mixture can be obtained by opening the package.

  In addition, when it is desirable that different substances are stored in the two storage area portions 11 and 12 without being mixed before mixing, the substances are separately stored in the storage area portions 11 and 12, respectively. In a state in which the communication path 21 is accommodated, the communication paths 21 and 22 may be closed with clips or the like. And when mixing of a substance is required, the state which pinched | interposed the communication paths 21 and 22 may be cancelled | released, and mixing of a substance may be performed as mentioned above. In addition, you may perform the method of plugging the communicating paths 21 and 22 by what kind of method.

Here, the experimental result which generated the microbubble in the liquid using the package 1 mentioned above is shown. In the experiment, the size and number of microbubbles generated in the liquid were examined by video analysis. As a result, it was observed that 2 to 1.4 billion nanobubbles having 1 to 1000 nm were generated per 1 cm ^{3 of} liquid. When a general bubble generating device is used, only about 3000 to 50 million microbubbles are generated per 1 cm ^{3 of} liquid, whereas in the package 1 according to the present invention, a liquid having a larger amount of dissolved nanobubbles. Can be generated.

  As shown in FIG. 1, the packaging body 1 has a plurality of discharge passages 31 and 32 formed between two sheet bodies. Specifically, the discharge passages 31 and 32 are formed in the outer periphery forming portion that forms the outer periphery of the sheet body that forms the package 1 itself. In the example of FIG. 1, first, three pieces are communicated with the internal space of the first storage area portion 11 and on the outer peripheral side opposite to the second storage area portion 12 side with respect to the first storage area portion 11. One discharge passage 31 having a predetermined length is formed. Moreover, it has one predetermined length on the outer peripheral side that communicates with the internal space of the second storage area portion 12 and is opposite to the first storage area portion 11 side with respect to the second storage area portion 12. The other discharge passage 32 is formed. As described above, the number of the discharge passages constituting each of the one discharge passage 31 and the other discharge passage 32 is different. However, one discharge passage 31 and the other discharge passage 32 may have the same number of discharge passages.

  Each of the discharge passages 31 and 32 is formed to have a predetermined length, and a discharge port serving as an end opposite to the side of each of the containing region portions 11 and 12 that communicates is an outer periphery forming portion of the packaging body 1. It is in a state of being blocked by. That is, the discharge ports of the discharge passages 31 and 32 are blocked by the two sheet bodies constituting the package body 1 being bonded together. In addition, although each discharge channel | path 31 and 32 is illustrated so that it may be set to the same thickness, thickness may differ, respectively.

  Corresponding to the discharge passages 31 and 32, cut portions 41a and 42a of the outer periphery forming portion of the package 1 in which the discharge passages 31 and 32 are formed are set, and notches for defining the cut portions 41 and 42 are formed on the outer edge of the package 1. For example, corresponding to one discharge passage 31, a cut portion 41 a that cuts three discharge passages 31 is set, and a cutout 41 that serves as a cut end of the cut portion 41 a and facilitates cutting is provided. Is formed. A cut portion 42a that cuts one discharge passage 32 is set corresponding to the other discharge passage 32, and a notch 42 that serves as a cut end of the cut portion 42a to facilitate cutting is provided. Is formed.

  And when using the liquid containing the microbubble produced | generated in the package 1 as mentioned above, the discharge port of the said discharge passages 31 and 32 is opened, and a liquid is discharged. At this time, the cutting location of the package 1 is changed according to the amount of liquid to be used. For example, in order to reduce the amount discharged at one time, as shown in FIG. 5 (a), the other discharge passage is cut from the notch 42 on the other discharge passage 32 side consisting of one discharge passage. 32 is cut and the discharge port is opened. On the other hand, when the amount to be discharged at a time is increased, as shown in FIG. 5B, one discharge passage is cut from a notch 41 on the side of one discharge passage 31 consisting of three discharge passages. All three discharge passages 31 constituting 31 are cut to open the discharge ports.

  Thus, in the packaging body 1 of the present invention, the numerical aperture of the discharge passage can be changed by changing the cutting location of the outer periphery forming portion. For example, in the example of FIG. 5, the state can be changed between a state where one discharge passage 32 is opened and a state where three discharge passages 31 are opened. Thereby, since a required amount of liquid containing microbubbles immediately after generation can be obtained, a liquid having a large amount of dissolved microbubbles can be obtained.

  Then, for example, by mixing the cosmetic liquid and hydrogen, a cosmetic with a large amount of dissolved hydrogen microbubbles can be obtained, and the discharge passages 31 and 32 are opened so as to discharge the amount corresponding to the application location. Can be made. In the package of the present invention, any material may be mixed. For example, you may utilize for mixing liquids, such as a cleaning agent, a chemical | medical agent, and a drink, and gases, such as oxygen and hydrogen. As a result, it is possible to obtain a mixture immediately after oxygen and hydrogen nanobubbles are generated and contained, and by using such a mixture, a living body such as a human body such as a growth promoting effect, an antioxidant action, and a bactericidal action by nanobubbles is obtained. An excellent effect can be expected. Note that the substances to be mixed may be liquids or gases. As a result, an appropriate amount of a mixture effective immediately after generation can be obtained.

  In the above, the discharge amount of the liquid containing the microbubbles is changed by changing the number of the discharge passages 31 and 32 positioned for each cutting point, but the thickness of the discharge passages 31 and 32 is changed. You may change the discharge amount. For example, in the example of FIG. 5, three discharge passages 31 are provided and one discharge passage 32 is provided as the other discharge passage 31, but one or the other discharge passages 31, 32 are configured by one or the same number. The one side may be constituted by a discharge passage that is thicker than the other side. Even in this case, the discharge amount can be changed between the state where one discharge passage 31 is opened and the state where the other discharge passage 32 is opened.

  Next, another configuration example of the package 1 will be described with reference to FIGS. In this example, the formation position of the discharge passage described above is different.

  First, in the example of FIG. 6A, three discharge passages 33 and 34 communicating with the internal space of the first housing region 11 are formed. Of the three discharge passages, one central discharge passage 34 is formed longer than the others. In other words, the two discharge passages 33 at both ends are formed shorter than the central discharge passage 34.

  Corresponding to the discharge passages 33, 34, cut portions 43a, 44a of the outer periphery forming portion of the package 1 in which the discharge passages 33, 34 are formed are set, and notches for defining the cut portions 43 and 44 are formed on the outer edge of the package 1. For example, in accordance with the length of the central discharge passage 34 formed longer than the others, a cutting point 44a (first cutting point) that cuts only the discharge passage 34 is set. A notch 44 is formed which becomes an opening 44a and facilitates cutting. Also, corresponding to the length of the two short discharge passages 33, a cutting point 43a (second cutting point) that cuts the two discharge passages 33 and the central discharge passage 34 is set, A cutout 43 is formed which becomes a cut end of the cut portion 43a and facilitates cutting.

  And when using the liquid containing the microbubble produced | generated in the package 1 as mentioned above, the discharge port of the said discharge passages 33 and 34 is opened, and a liquid is discharged. At this time, the cutting location of the package 1 is changed according to the amount of liquid to be used. For example, when reducing the amount discharged at a time, as shown in FIG. 7A, only one discharge passage 34 is cut by cutting from a notch 44 corresponding to one long discharge passage 34. To open the outlet. On the other hand, when increasing the amount to be discharged at one time, as shown in FIG. 8A, cut from the notch 43 corresponding to the short discharge passage 33 and cut all the discharge passages 33 and 34. The discharge ports of all the discharge passages 33 and 34 are opened.

  Thus, in the packaging body 1 of the present invention, the numerical aperture of the discharge passage can be changed by changing the cutting location of the outer periphery forming portion. For example, in the example of FIG. 6A, the state can be changed between a state in which one discharge passage 34 is opened and a state in which three discharge passages 33 and 34 are opened. Thereby, since a required amount of liquid containing microbubbles immediately after generation can be obtained, a liquid having a large amount of dissolved microbubbles can be obtained.

  In addition, FIG.6 (b) is an example from which the surrounding shape of the discharge passages 33 and 34 differs with respect to Fig.6 (a) mentioned above. That is, in FIG. 6B, the portions where the discharge passages 33 and 34 are formed are formed so as to protrude further outward from the periphery of the first storage region portion 11. And the notch 43,44 used as the cut-out part of the cutting location 43a, 44a formed corresponding to each discharge passage 33, 34 from which length differs like the above-mentioned is formed in the outer edge of the site | part formed protrudingly. Yes. These notches 43 and 44 are cut as shown in FIGS. 7B and 8B, respectively, so that one discharge passage 34 is opened and three discharge passages 33 and 34 are opened. It can be changed to the state.

  In the example of FIG. 6 described above, the case where the three discharge passages 33 and 34 are formed and only one is formed in the long discharge passage 34 has been described, but the number of the drainage passages 33 and 34 is as described above. It is not limited to. For example, a plurality of drain passages 34 that are longer than the others may be formed.

  Furthermore, a modified example of the present invention will be described with reference to FIGS. First, although not shown, the package 1 in the present invention is not limited to two communication paths as shown in FIG. 1 and the like, and may include more communication paths.

  Moreover, the package 1 may be provided with more accommodation area | region parts. For example, although not shown, in addition to the first accommodation area 11 and the second accommodation area 12, a third accommodation area may be provided. Along with this, a communication path through which the substance flows from the third storage area part toward the first storage area part 11, a communication path through which the substance flows from the first storage area part 11 toward the third storage area part, May be provided. In some cases, a communication path may be provided between the second storage area and the third storage area.

  And each different area | region part may accommodate a respectively different substance beforehand. For example, liquid may be stored in the first storage region portion, and different gases may be stored in the second storage region portion and the third storage region portion. In the configuration as described above, the substances in each accommodation area can be mixed by repeatedly pressing each accommodation area.

  Moreover, although the structure provided with the some communication path between a pair of accommodation area | region parts was shown above, although the package 1 of this invention is not illustrated, between a pair of accommodation area | region parts 11 and 12, Only one communication path may be provided. Even with such a configuration, the substance can be circulated between the accommodating region portions 11 and 12 via the communication path 25, and the substance can be mixed or the gas can contain gas microbubbles.

  At this time, the communication path may be filled with a honeycomb structure, for example. Specifically, the communication path may be configured such that a plurality of polygonal shaped objects such as hexagonal shaped objects are spread in the communication path, and the substance flows through the gaps between these polygonal shaped objects. In addition, the polygon-shaped thing in a communicating path may be formed, for example, by thermocompression-bonding the two sheet bodies which form the packaging body 1 to a polygon, or you may spread a polygon-shaped thing. .

  Here, in the above description, the outer shape of the packaging body 1 is a rectangle, and the two storage area portions 11 and 12 are also illustrated in a rectangular shape. However, the shape of the packaging body 1 and the storage area portions 11 and 12 is as follows. Any shape is possible. For example, the outer shape may be a heart shape, a rhombus, or an ellipse as shown in FIG. At this time, the storage area portions 11 and 12 may have a shape obtained by substantially dividing the outer shape of the package 1 itself.

  In the example of FIG. 9, the outer shape is a heart shape, and each of the storage area portions 11 and 12 is formed in a shape in which the heart shape is divided into left and right at the center, and the lower end portions thereof are respectively extended to the discharge passage. 35 is formed. And the cutting location 45a which cut | disconnects the front-end | tip vicinity of the discharge passage 35 is set, and the notch 45 used as the cut end of the said cutting location 45a is formed. By cutting the notches 45 as shown in FIG. 9B, the discharge passage 35 is opened.

  In the packaging body 1 of the present invention, the first storage area portion 11 and the second storage area portion 12 are not necessarily limited to the same shape. For example, as shown in FIG. 10 (a), each package region 1 has a rectangular outer shape, the first container region 11 is square, the second container region 12 is triangular, and so on. , 12 may be different in shape. And the front-end | tip part of the triangular 2nd accommodating area | region part 12 is extended, and the two discharge passages 36 are formed. Correspondingly, a cutting point 46a for cutting the vicinity of the tip of the discharge passage 36 is set, and a notch 46 serving as a cut end of the cutting point 46a is formed. By cutting the notch 46 as shown in FIG. 10B, the discharge passage 36 is opened.

  Furthermore, in the example of FIG. 10, the first storage area 11 and the second storage area 12 are folded along a center line C such that the shapes of the first storage area 11 and the second storage area 12 are line symmetric, as shown in FIG. Half of the area part 11 and the second accommodating area part 12 are folded. For this reason, it becomes easy to press the 1st storage area part 11 and the 2nd storage area part 12, and it becomes easy to discharge the liquid from the discharge channel 36. Furthermore, by folding as shown in FIG. 10C, the strength of the package 1 itself is increased, and the package 1 can be inserted into the soil from the discharge port of the discharge passage 36. Thereby, it can utilize also for supplying the nutrient of a plant.

  Moreover, although the case where two sheet bodies were bonded together and the package body 1 was comprised was illustrated above, the package body 1 may be what kind of structure. For example, each of the storage area portions may be formed of a container, and the communication path may be formed of a tube or a through hole. As another configuration example of the package 1, the package 1 having the configuration shown in FIG. 11 will be described. The package 1 shown in this figure is an intermediate region formed by two substantially cylindrical storage region portions 11 and 12 having flexibility and an internal space, the outer shape of which is narrower than the storage region portions 11 and 12. 14 is connected. And in the intermediate | middle area | region 14, the member which forms the outer surface of the package 1 in the center part 14a is bonded together, and the said center part 14a is the state closed. As a result, the space formed between the central portion 14a located around the central portion 14a and the outer surface communicates the internal space between the first storage region portion 11 and the second storage region portion 12. 28. As described above, the communication path 28 is formed to be extremely small, and is configured to make the gas in the liquid into microbubbles when the liquid flows. In addition, a discharge passage that is open to the outside is formed at the tip of the first accommodating region 11, and a discharge port that is an open end is closed by a cap 30. The communication path 28 is not necessarily limited to the configuration described above. For example, the first storage region portion 11 and the second storage region portion 12 are connected via an intermediate member, and the first storage region portion 11 and the second storage region portion 12 are communicated with the intermediate member. A passage may be formed.

  In the package 1 having the above-described configuration, the liquid containing the gas in each of the storage area portions 11 and 12 can communicate with the communication path 28 by alternately grasping the first storage area portion 11 and the second storage area portion 12. It will be distributed. Thereby, the liquid containing a microbubble can be produced | generated like the above-mentioned. Then, by removing the cap 30 and opening the discharge port of the discharge passage, the liquid containing microbubbles can be discharged. For example, when the liquid is a liquid fertilizer for plant cultivation, the liquid fertilizer containing microbubbles can be added to the plant by stabping the package 1 shown in FIG. 11 into the soil of a pot or a planter from the discharge port side. Can be given.

  Moreover, as shown in FIG. 12, the packaging body 1 of this invention may form each accommodating area | region parts 11 and 12 and the communicating path 23 which connects between these with elastic members, such as rubber | gum. In the example of FIG. 12, the inside of the communication path 23 has a honeycomb structure. Furthermore, in the example of FIG. 12, a discharge passage 37 that communicates with the inside of the second storage region portion 12 is formed, and a cap 37 a is provided at a discharge port that is an open end of the discharge passage 37. With such a configuration, it is possible to generate a liquid containing a large amount of microbubbles by pressing each of the storage area portions 11 and 12 alternately with a hand or a leg. Thus, the liquid produced | generated in large quantities can be utilized as an agrochemical etc., for example.

  In addition, although the case where the two accommodation area | region parts 11 and 12 were connected directly above was illustrated, as shown in FIG. 13, intermediate accommodation between the 1st accommodation area | region part 11 and the 2nd accommodation area | region part 12 is carried out. A region portion 15 may be provided. And the 1st or several 1st continuous channel | path 24 which makes the 1st accommodating area | region part 11 and the intermediate | middle accommodating area | region part 15 communicate, and the one or more which makes the 2nd accommodating area | region 12 and the intermediate | middle accommodating area | region 15 communicate. The second communication passage 25 is provided. Furthermore, a discharge passage communicating with any one of the storage area portions 11, 12, 15 is formed. In such a configuration, by pressing only the first storage region portion 11 and the second storage region portion 12 at both ends, the substance circulates through the communication passages 24 and 25 via the intermediate storage region portion 15, and more efficiently. Bubbles can be generated. And a required quantity of liquid can be discharged | emitted by discharging | emitting the liquid containing a microbubble from a discharge channel.

  Although the present invention has been described with reference to the above-described embodiment and the like, the present invention is not limited to the above-described embodiment. Various changes that can be understood by those skilled in the art can be made to the configuration and details of the present invention within the scope of the present invention.

  The present invention relates to a patent application of Japanese Patent Application No. 2006-204402 filed on October 18, 2016 in Japan, and Japanese Patent Application No. 2017 filed on April 14, 2017 in Japan. The benefit of the priority claim based on the -080429 patent application is enjoyed, and all the contents described in the patent application are included in this specification.

DESCRIPTION OF SYMBOLS 1 Package 11 1st accommodating area | region 12 2nd accommodating area | region 14 Intermediate | middle area 15 Intermediate | middle accommodating area | region parts 21-25 Communication path 21a Protrusion 21b Porous body 30, 37a Cap 31-37 Outlet path 41-46 Notch 41a ~ 46a Cutting point

Claims (4)

A first storage region portion and a second storage region portion having an internal space for storing a plurality of substances;
The substance is circulated, and includes a communication path that allows the internal space of the first storage region portion and the internal space of the second storage region portion to communicate with each other.
The first storage region portion and the second storage region portion are configured such that the internal space is reduced / expanded according to an external pressure, and the internal spaces of the first storage region portion and the second storage region portion are reduced. / The substance is configured to flow through the communication path in response to expansion,
At least one of the substances is a gas, and at least the other one is a liquid capable of containing gas bubbles,
The communication path is configured to microbubble the gas in the liquid when the substance flows.
And a plurality of discharge passages communicating with at least one internal space of the first storage region portion and the second storage region portion and having a discharge port for discharging the substance from the internal space,
By cutting the outer periphery forming portion from a state where all of the discharge ports of the discharge passage are closed by the outer periphery forming portion of the member forming the package itself, the discharge port of the discharge passage is opened. It is configured to be changeable, and is configured to be able to change to a plurality of different states of the discharge port by cutting the outer periphery forming portion at different cutting locations.
One discharge passage which is a predetermined number of the discharge passages communicating with the internal space of the first storage region portion and the other discharge passage which is a predetermined number of the discharge passages communicating with the internal space of the second storage region portion And comprising
The number of the discharge passages is different between the one discharge passage and the other discharge passage,
The cutting location for cutting the outer periphery forming portion so that the one discharge passage is opened is different from the cutting location for cutting the outer periphery forming portion so that the other discharge passage is opened.
Packaging body. The package according to claim 1,
A plurality of the discharge passages communicating with at least one internal space of the first storage region portion and the second storage region portion;
At least one of the plurality of discharge passages is formed longer than the other,
By cutting the outer periphery forming portion at the first cutting location, at least one of the plurality of discharging passages is opened longer than the other, and the second cutting location is different from the first cutting location. The plurality of discharge passages are all opened by cutting the outer periphery forming part.
Packaging body. The package according to claim 1 or 2 ,
For each different cut location, a notch that defines the cut position of the cut location is formed on the outer edge of the package,
Packaging body. The package according to any one of claims 1 to 3,
A part of two flexible sheet bodies are bonded together,
Between the two sheet bodies, an internal space of the first storage region portion, an internal space of the second storage region portion, the communication passage, and the discharge passage are formed,
The discharge port of the discharge passage is in a state of being blocked by bonding the two sheet bodies,
The discharge port of the discharge passage is opened by cutting the outer periphery forming portion formed around the first storage region portion and / or the second storage region portion by bonding the two sheet bodies. It is configured,
Packaging body.

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