JP4036946B2 - Refill container, filling system for use, and method for manufacturing refill container - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an on-use filling system, and a stock solution replenishing device and a refill container used therefor. More specifically, a filling solution system and a refill container that can be suitably used for filling a small-capacity container in a small volume container at home and spraying or discharging the concentrate with a propellant pressure. About.
[0002]
[Prior art]
Conventional aerosol products are packaging containers configured by attaching an aerosol valve to the opening of a pressure-resistant container body, filling the container body with stock solution and propellant, and attaching a push button to the stem of the aerosol valve. . This can open an aerosol valve by pressing a push button, and the filled stock solution (including a semi-fluid) can be ejected in a sprayed state, in a foamed state or in a liquid state. When the stock solution runs out, the remaining propellant is removed and the entire aerosol product is discarded. In addition, aerosol type dispenser devices that discharge with a low-pressure propellant that is not classified as an aerosol product according to the standard are also used in the same manner as described above.
[0003]
For propellants, compressed gases such as nitrogen gas, air, and carbon dioxide, and liquefied gases such as LPG, liquefied natural gas, dimethyl ether, and chlorofluorocarbons are used. In addition to the usual aerosol products that are filled with the propellant and the stock solution, a double aerosol product that separates and stores the stock solution and the propellant with a flexible inner bag, cylinder and piston, etc. Is used.
[0004]
In some hair dyes, adhesives, and the like, a plurality of stock solutions are separated and stored, and these stock solutions are mixed and used immediately before use. When such a two-component mixed type stock solution is used as an aerosol product, it is separately stored in two aerosol devices, and ejected from one spout etc. while mixing the stock solution led from each discharge port on the way I try to let them.
[0005]
On the other hand, a container provided with a pump is used as a packaging container for shampoo, liquid toothpaste, and the like. This pump discharges the liquid in the cylinder (including the semi-fluid) from the discharge port at the upper end of the piston when pushing the piston of the pump, and the tube provided in the pump when the piston is returned by the spring. It sucks up into the cylinder. In the case of such a container with a piston, even when the contents are used up, the liquid can be filled from a refill pack (refill pack) containing liquid in a laminate sheet or the like and used repeatedly.
[0006]
[Problems to be solved by the invention]
The present invention makes it possible to repeatedly use an aerosol product or a dispenser product, which has been used in a disposable manner, in a home as well as a container with a pump, and in particular, can be filled in an amount to be used immediately before use. This is a technical issue. Furthermore, this invention makes it a technical subject to provide the stock solution replenishment apparatus and refill container which can be suitably employ | adopted for such a filling system at the time of use.
[0007]
[Means for Solving the Problems]
  Of the present inventionThe refill container has a translucent container body, an aerosol valve attached to the opening of the container body, and a translucency connected to the inner side of the aerosol valve so that the lower end side communicates with the inside of the container body. A cylinder and a piston that is slidably fitted in the cylinder. The upper part of the piston in the cylinder is filled with a raw solution, and a compressed gas is provided between the lower part of the piston in the cylinder and between the cylinder and the container body. And is configured to tilt when the piston reaches the lower end of the cylinderIt is characterized by that.
[0008]
  In the refill container of claim 2,A protrusion is eccentrically formed on the lower surface of the piston.And claim 3In the refill container, the container body is made of a bottomed cylindrical synthetic resin, and an aerosol valve is bonded to the upper end opening. Further, in the refill container according to a fourth aspect of the present invention, the aerosol valve is provided with a fixed amount injection mechanism capable of injecting a certain amount. In the refill container of claim 5, a push button for opening and closing the aerosol valve is attached to the aerosol valve.
[0009]
The in-use filling system of the present invention includes the above-described refill container of the present invention and a stock solution replenishing device for filling the stock solution in a cylinder of the refill container, and the stock solution replenishing device accommodates the stock solution. And a connecting means for detachably connecting to the outlet side of the aerosol valve of the refill container. The on-use filling system according to claim 7 is a pump in which the pressurizing means is attached to the mouth of the stock solution container. 9. The on-use filling system according to claim 8, wherein the pressurizing means communicates / blocks a partition wall that variably isolates the interior of the stock solution container into at least two chambers, a first chamber that fills the stock solution, and the outside. And a compressed gas filled in another chamber to pressurize the first chamber. In the in-use filling system according to claim 9, the stock solution replenishing device is provided with a check valve for blocking back flow from the refill container side.
[0010]
The refill container manufacturing method of the present invention includes a container main body, an aerosol valve attached to the opening of the container main body, a cylinder connected to the inner side of the aerosol valve so that a lower end side communicates with the inside of the container main body, A refill container manufacturing method comprising: a piston slidably fitted in a cylinder, wherein the piston is tilted when the piston reaches the lower end of the cylinder, through an aerosol valve; The cylinder is filled with compressed gas, so that the piston moves down in the cylinder, the piston abuts the bottom surface of the container body, the piston tilts, and communicates with the upper and lower sides of the piston. The space between them is filled, and then the compressed gas in the cylinder is discharged through the aerosol valve, so that the piston rises in the cylinder, Stone is characterized in that sealing the upper and lower piston in the cylinder.
In the refill container manufacturing method according to the eleventh aspect, the protrusion is eccentrically provided on the lower surface of the piston, the lower surface of the piston contacts the bottom surface of the container body, and the piston is inclined. In a refill container manufacturing method according to a twelfth aspect of the present invention, the piston moves up in the cylinder, and after the piston seals the upper and lower sides of the piston in the cylinder, the stock solution is pressurized and filled into the cylinder from the aerosol valve.
[0011]
  The second aspect of the method for producing a refill container of the present invention is:A container body, an aerosol valve attached to the opening of the container body, a cylinder connected to the inner side of the aerosol valve so that a lower end side communicates with the inside of the container body, and a slidably fitted in the cylinder A refill container including a piston, and a cylinder and a piston are inserted into a container body having a flat bottom, an aerosol valve is attached to an opening of the container body, and the aerosol valve is inserted into the cylinder through the aerosol valve. Filled with compressed gas, thereby lowering the piston in the cylinder, the piston abuts the bottom surface of the container body, communicating the upper and lower sides of the piston, and the compressed gas is filled into the space between the container body and the cylinder; The compressed gas in the cylinder is evacuated through the aerosol valve, and then in the center of the bottom of the container body so as to face the cylinder and There compressed gas is characterized by falling into the cylinder, to form a curved projection when down to the lower end.
15. The method for manufacturing a refill container according to claim 14, wherein the refill container is provided with a piston and includes a piston seal that seals the upper and lower sides of the piston, and the piston is in contact with the flat bottom surface of the container body. After the seal is positioned below the lower end of the cylinder and the curved protrusion is formed at the center of the bottom of the container body, the piston seal is positioned above the lower end of the cylinder when the piston descends to the lower end. In the refill container manufacturing method according to the fifteenth aspect, after the curved protrusion is formed, the stock solution is pressurized and filled into the cylinder from the aerosol valve.
[0012]
[Operation and effect of the invention]
  Claim 1The refill container has a translucent container body, an aerosol valve attached to the opening of the container body, and a translucency connected to the inner side of the aerosol valve so that the lower end side communicates with the inside of the container body. Because it has a cylinder and a piston that is slidably fitted in the cylinder,The amount of stock solution used and the amount remaining can be immediately determined from the outside by the position of the piston. Therefore, excessive use can be prevented and the time when refilling should be easily understood. In addition, it can be easily seen from the outside that the refill container is full at the time of refilling. Further, when a capacity scale or a single use amount scale is provided on the cylinder, the single use amount can be accurately measured.In the refill container of claim 1, the upper part of the piston in the cylinder is filled with the stock solution, the compressed gas is filled between the lower part of the piston in the cylinder and between the cylinder and the container body, and the piston reaches the lower end of the cylinder. Is configured to tilt,When the compressed gas is filled between the cylinder and the container main body via the valve and the cylinder, the piston reaches the lower end and tilts, and the communication state between the cylinder and the space between the cylinder and the container main body is improved. Therefore, the filling operation is easy.
[0013]
In the refill container according to the second aspect, since the protrusion is eccentrically provided on the lower surface of the piston, the piston is in contact with the bottom surface of the container body, and the piston is inclined.
[0014]
In the refill container of claim 4, the saidThe aerosol valve has a fixed-quantity injection mechanism that can inject a certain amount.For,Each time the aerosol valve is opened, a substantially constant amount of stock solution can be injected.
[0015]
The in-use filling system according to claim 6.In order to fill the refill container with the stock solution, a connecting portion of the stock solution replenishing device is attached to the outlet side of the valve of the refill container, and the stock solution is filled from the stock solution replenishing device. then,CylinderThe piston descends as the stock solution is filled inside. AndSpace between cylinder and container bodyThe volume decreases according to the amount of filling, and the compressed gas is pressurized. When filling is completed, the connecting portion of the stock solution replenishing device is removed. When a push button is attached to this refill container and the valve is opened by operating the push button, the stock solution is ejected from the push button nozzle or spout with the pressure of compressed gas, just like a normal aerosol product or dispenser product, Ejection stops when the push button is released.
  When the stock solution in the refill container is used up, the stock solution is replenished again from the stock solution replenishing device. Thus, in the in-use filling system according to claim 6, only the undiluted solution is ejected, and the compressed gas as the propellant ispistonIsolated bySpace between cylinder and container bodyBecause it does not come out of the, it can be used repeatedly.
  The in-use filling system according to claim 7 is a stock solution replenishing device,A so-called pumped container is used. Therefore, it is easy to refill the stock solution replenishing device, and it can be refilled any number of times.The in-use filling system according to claim 8 comprises:A so-called multi-chamber container (or a double aerosol device) is used as a stock solution container, and the user can easily send out the stock solution simply by operating a valve. In addition, unlike a container with a pump, the stock solution is stored in a state where it is cut off from air. Therefore, there is an advantage that even a stock solution containing a component that decomposes or loses its activity upon contact with air can be used.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
Next, embodiments of the in-use filling system and the refill container of the present invention will be described with reference to the drawings. FIG. 1 is a partially sectional side view showing an embodiment of the filling system at the time of use of the present invention, FIG. 2a is a sectional view showing an embodiment of the refill container of the present invention, and FIG. FIG. 3 and FIG. 4 are sectional views showing an embodiment of the adapter according to the present invention, and FIG. 5a and FIG. 5b are each an embodiment of a container with a pump according to the present invention and the main part showing its operation state. Sectional drawing, FIG. 6 is principal part sectional drawing which shows further another embodiment of the container with a pump concerning this invention, FIG. 7 is the operation state explanatory drawing, FIG. 8 is other embodiment of the stock solution replenishing apparatus concerning this invention 9 is a sectional view showing a double aerosol product in the stock solution replenishing device, FIG. 10 is a sectional view showing still another embodiment of the refill container according to the present invention, FIGS. 11a and 11b, and FIG. 12a 12b is an explanatory view showing the procedure for filling the refill container of FIG. 10 with compressed gas and stock solution, FIG. 13 is a front view showing still another embodiment of the in-use filling system of the present invention, and FIG. 14a is the present invention. Sectional drawing which shows other embodiment of the push button used for the refill container of FIG. 14, FIG. 14b and FIG. 14c are explanatory drawings which show the operation state, FIG. 15a shows further another embodiment of the push button used for the refill container of this invention. 15b is an enlarged cross-sectional view of the main part thereof, and FIGS. 16 and 17 are cross-sectional views of the main part showing still another embodiment of the refill container of the present invention.
[0018]
The in-use filling system A in FIG. 1 includes a refill container 1 and a stock solution replenishing device 2. In this embodiment, the refill container 1 is a so-called small-volume aerosol product, and has, for example, the form shown in FIG. The stock solution replenishing device 2 includes a container 3 with a pump, a tube 4 connected to the outlet of the pump, and an adapter 5 connected to the tip of the tube.
[0019]
As shown in FIG. 2 a, the refill container 1 includes a container main body 7 and a valve 9 attached to the upper end opening of the container via a gasket 8. A push button 11 is detachably attached to the stem 10 of the valve. Further, a cylinder 12 is concentrically connected to the lower end of the valve 9, and a piston 13 is slidably accommodated in the cylinder 12. The piston 13 is a so-called free piston that does not have a piston rod. A piston seal 14 is fitted around the piston 13. The upper part of the cylinder 12 is somewhat thinner for attachment to the valve 9 and the lower end is open. What is necessary is just to insert the piston 13 from the lower end side.
[0020]
The interior of the refill container 1 is partitioned by the piston 13 into a first chamber 19 that is an upper range from the piston in the cylinder 12 and a second chamber 20 that is another portion in an airtight state in a variable volume manner. . The first chamber 19 is filled with a stock solution G to be ejected, and the second chamber 20 is filled with a compressed gas E. Further, the center of the bottom of the container body 7 is provided with a curved protrusion 7a so as to face the cylinder 12, but this is somewhat separated from the bottom surface of the container body 1 when the piston 13 descends to the lower end. It is for maintaining the state.
[0021]
That is, in this embodiment, when the compressed gas E is filled, the bottom surface 7b of the container body is made flat as shown in FIG. 2b, and the compressed gas E is filled from the valve 9 of FIG. As a result, when the lower end of the piston 13 is in contact with the bottom surface 7b, the piston seal 14 is positioned below the lower end of the cylinder 12, and the inside and outside of the cylinder communicate with each other. Therefore, the compressed gas E can be easily filled in the second chamber 20 outside the cylinder 12. Next, when the compressed gas E in the cylinder 12 is extracted through the valve 9, the piston 13 rises. In this state, the curved protrusion 7a is formed. Therefore, when a user or the like next fills the cylinder 12 with the stock solution G from the valve 9, the piston 13 does not descend to the lower end, the stock solution G leaks into the second chamber 20, or the compressed gas E enters the stock solution G. Don't do it. In addition, you may employ | adopt what has the effect | action of a non-return valve as the piston seal 14. FIG. In that case, the lower end of the cylinder 12 may be extended to near the bottom of the container.
[0022]
The valve 9 is conventionally known, and includes a housing 15, the above-described stem 10 slidably provided up and down in the housing, a spring 16 that constantly biases the stem upward, a housing 15 and a stem. 10 is provided with a valve rubber 17 interposed between 10 and a mounting cap 18 for attaching the housing 15 to the container body. In addition, the stem 10 may be opened by a tilting operation in addition to sliding up and down.
[0023]
The type of the stock solution G to be filled in the first chamber 19 is not particularly limited. However, since the refill container 1 is small, pharmaceuticals, quasi-drugs, cosmetics, miscellaneous goods, etc. that are carried in handbags when going out are suitable. . The stock solution may be a normal liquid, a high viscosity product such as cream or gel, and a foamed product.
[0024]
Examples of the above-mentioned pharmaceuticals include anti-inflammatory analgesics, nasal drops, eye drops, wounds and the like, and quasi-drugs include hair dyes, mouth refreshing agents, anti-smell agents, antiperspirants, hair restorers, permanents. Wave agents, bath agents, medicated cosmetics, medicated toothpastes, repellents, insecticides and the like can be mentioned. Cosmetics include hair creams, hair sprays, hair foams, hair tonics, hair dyes and other hair, after-shave lotion, general lotion, eau de cologne, sun lotion and other lotions, cleansing creams, shaving creams, and emulsions. , Creams such as cold cream and hand cream, cosmetic oils such as baby oil, and cosmetics for packs. Examples of miscellaneous goods include industrial goods, car goods, and household goods such as deodorants and glass cleaners.
[0025]
Examples of the compressed gas E include air, nitrogen gas, carbon dioxide, nitrous oxide, and a mixture thereof. The pressure in the second chamber 20 filled with the compressed gas varies depending on the purpose of use and the viscosity of the stock solution, but is, for example, about 0.05 to 1.0 MPa, more preferably about 0.2 to 0.8 MPa. . Further, the volume of the second chamber 20 filled with the compressed gas E is preferably 30% or more of the total volume (E + G) so that an appropriate injection pressure can be maintained even if the remaining amount of the stock solution G decreases.
[0026]
The container body 7 of the refill container 1 in FIG. 2 is made of a light-transmitting material, for example, a transparent or translucent synthetic resin or glass. The cylinder 12 is also made of a material such as a synthetic resin having translucency, and is further provided with a scale 12a that serves as a guide for the amount of the stock solution G. If the translucent container body 7 and the cylinder 12 are employed in this way, the state of the remaining stock solution can be immediately recognized from the outside depending on the position of the piston 13. Also, when filling, the appropriate amount is known. However, the refill container of the present invention is not limited to one having translucency. The stock solution may be colored.
[0027]
The container 3 with a pump of the stock solution replenishing device 2 in FIG. 1 includes a container body 21 and a pump 22 attached to the upper end opening. Although the container body 21 and the pump 22 can use conventionally well-known things, the pump 22 generate | occur | produces the pressurization force which can be filled with the undiluted | stock solution G with respect to the pressure of the compressed gas E with respect to the refill container 1. Shall. The tube 4 is preferably made of a synthetic resin having flexibility, but may have a rigidity such as a synthetic resin pipe or a metal pipe.
[0028]
As shown in detail in FIG. 3, the adapter 5 has a check valve 24 inside. That is, the adapter 5 has an upper half 25 and a lower half 26 that are screwed together with each other, and urges the ball 28 and the ball upward in a cylindrical space 27 formed in the upper half 25. The spring 29 is accommodated. The upper bottom surface of the void 27 is a tapered valve seat 30 with which the ball 28 abuts. A connection protrusion 31 for connecting to the tube 4 is provided on the upper half 25, and a communication hole 32 is formed from the tip of the connection protrusion 31 to the space 27. A recess 33 is formed on the lower surface of the lower half body 26 to be fitted to the stem 10 of the refill container 1, and a communication hole 34 is formed from the recess to the upper surface. When the stock solution G is sent from the stock solution replenishing device 2 side to the refill container side by the pump 22, the adapter 5 does not hinder the flow because the balls 28 escape downward. When the pressure generated by the pump 22 decreases, the ball 28 contacts the valve seat 30 with the biasing force of the spring 29 and the pressure of the stock solution G from the refill container 1 side, so that the stock solution G does not flow back.
[0029]
1 to 3 configured as described above, while the stock solution G remains in the refill container 1, the refill container 1 can be used in the same manner as a normal aerosol product. That is, in a state where the push button 11 is not pushed, the piston 13 is constantly urged upward by the pressure of the compressed gas E in the container body 7, and an equivalent pressure is also applied to the stock solution G. When the push button 11 is pressed, the stem 10 is lowered, the valve rubber 17 is deformed, and the inside of the stem 10 and the inside of the container body 7 communicate with each other by a small hole (reference numeral 10a in FIG. 2) formed in the stem 10. To do. The pressurized stock solution G passes through the stem 10 and is ejected to the outside from the nozzle (reference numeral 11a in FIG. 2) of the push button 11 or the spout. When the push button 11 is released, the stem 10 is raised by the urging force of the spring 16 to return to the original state.
[0030]
When the stock solution G is ejected, the piston 13 moves up in the cylinder 12. The remaining amount of the stock solution G at that time is immediately known from the outside because the container body 7 and the cylinder 12 have translucency. The stock solution is replenished from the stock solution replenishing device 2 when the remaining amount of the stock solution G runs out or decreases, or when it is next used. That is, first, the push button 11 is removed from the stem 10, and the adapter 5 is attached to the stem 10. Then, the pump 22 of the container 3 with the pump is operated while pushing the stem 10 with the adapter 5 to fill the refill container 1 with the stock solution G in the container body 21 via the tube 4. At that time, the check valve 24 prevents the stock solution from flowing back from the refill container 1 side to the stock solution replenishing device 2 side.
[0031]
As described above, the refill container 1 can be filled whenever the stock solution G runs out or immediately before use, so the capacity of the refill container 1 itself may be small. Therefore, the refill container 1 can be a small product that is convenient to carry, and can be used only by a push button operation equivalent to a normal aerosol product. Moreover, since the refill container 1 itself can be reused any number of times, it is preferable from the viewpoint of environmental protection. Further, the refill container 1 is not always filled with the stock solution, but can be replenished and used up from the stock solution replenishing device 2 just before use. In that case, fresh stock solutions can always be used. Further, each of the two-liquid mixed-type stock solutions can be filled in separate stock solution replenishing devices, filled in one refill container immediately before use, stirred and mixed, and sprayed. As the two-component mixed stock solution, there are a two-component hair dye, a two-component adhesive, a two-component reactive cosmetic, for example, a wrinkle-stretching agent containing an enzyme that exhibits activity when contacted with water, a whitening agent, and the like. The stock solution may be 3 or more.
[0032]
In the adapter 5 of FIG. 3, the ball 28 is urged by the spring 29, but if the communication hole 34 of the lower half 26 is smaller in diameter than the ball 28, the spring 29 can be omitted. Further, as shown in FIG. 4, when the diameter of the communication hole 34 is larger than the diameter of the ball 28, an appropriate drop prevention means is provided to prevent the ball 28 from falling off, for example, by providing protrusions 35 radially. In this case, the spring can be omitted. When the spring 29 is omitted in the adapter 5 of FIG. 3 and the check valve 24A of the check valve 24A of the adapter 5A of FIG. 4 is substantially the same as that having the spring 29 described above.
[0033]
In the case of FIG. 3, the check valve 24 is provided on the adapter 5, but the check valve 24 </ b> B may be provided on the pump-equipped container 3 </ b> A side as shown in FIG. 5. As shown in FIG. 5a, the container 3A with a pump divides a piston rod 36 for operating the pump into an upper half 36a and a lower half 36b, and a check valve 24B is provided inside the lower half 36b. Provided. The check valve 24 </ b> B is configured by providing a space 27, a valve seat 30 and a communication hole 32 in the lower half 36 b of the piston rod 36, and providing a ball 28 and a spring 29 in the space 27. In this case, as shown in FIG. 5 b, when the handle 38 at the upper end of the piston rod 36 is pushed downward to feed the stock solution, the ball 28 moves away from the valve seat 30 against the biasing force of the spring 29. When the piston rod 36 is released as shown in FIG. 5a, the ball 28 comes into contact with the valve seat 30 to prevent backflow against the pressure on the refill container side. Note that the spring 29 can be omitted also in the check valve 24B of FIG.
[0034]
The check valve 24 provided on the adapter 5 side in FIGS. 3 and 4 and the check valve 24B provided on the pump-equipped container 3A side in FIG. 5 may be provided on either side, but provided on both sides. Two check valves 24 and 24B may coexist. In that case, the back flow of the stock solution can be prevented more reliably.
[0035]
FIG. 6 shows an embodiment of a metering discharge pump suitably used for the pump-equipped containers 3 and 3A. The pump 40 has a cylinder 42 fitted to the upper portion of the container body 22 via a packing 41, a screw cap 43 for fixing the cylinder, and a hollow cylindrical shape slidably accommodated in the cylinder 42. Piston 44, and a spring 45 that constantly biases the piston upward. The cylinder 42 has a cup shape with a flange 46 at the upper end, and a guide cylinder portion 47 is formed in the lower portion so as to extend upward. The outer surface of the upper end of the guide cylinder portion 47 slides on the inner surface of the piston 44 in a fluid-tight manner. Contact freely. A cylindrical portion 50 that connects the dip tube 49 is formed below the guide cylindrical portion 47 so as to extend downward.
[0036]
Furthermore, the valve body 51 is accommodated inside the guide tube portion 47 so as to be movable up and down. A protrusion 52 is provided at the lower end of the valve body 51, and the protrusion 52 passes through an annular valve seat 53 formed on the inner surface of the guide tube portion 47. The lower end of the protrusion 52 is somewhat swelled, thereby restricting the rising end of the vertical stroke of the valve body 51. Further, the lower tapered surface 54 of the valve body 51 and the tapered surface 55 of the valve seat 53 constitute a lower sealing surface, and when the piston 44 descends, both come into close contact with each other to prevent back flow of the stock solution. By opening the piston 44 when it is raised, the stock solution can be sucked from below.
[0037]
The piston 44 is divided into a cylindrical lower piston 44a and a cylindrical upper piston 44b that is fitted to the upper end of the lower piston 44a so as to be vertically movable and nested. The upper part of the upper piston 44b is a communication hole 56 with a narrow inner diameter, and a needle 57 is slidably fitted up and down inside the large diameter part. The tapered surface 58 at the upper end of the needle 57 and the corner portion 59 of the step formed on the inner surface of the upper piston 44b constitute an upper sealing surface, and both come into close contact with each other when the piston 44 is raised. Inhalation of the liquid is prevented, and the undiluted solution can be delivered by opening the piston 44 when it is lowered.
[0038]
The inside of the piston 44 is a pump chamber 60 having a predetermined volume that is partitioned between the lower seal surface and the upper seal surface. A ball 61 for stirring the stock solution is accommodated in the pump chamber 60. ing. The spring 45 is sandwiched between an annular protrusion 62 provided on the outer periphery of the lower piston 44 a and an annular step 63 formed on the inner peripheral surface of the cylinder 42. A push button 64a or an operation handle having a discharge port 64 is attached to the upper end of the upper piston 44b.
[0039]
As shown in the agitation step S1 at the left end of FIG. 7, the fixed discharge pump 40 configured as described above is configured such that when the pump 40 is shaken up and down with the container body immediately before use, the balls 61 are undiluted solution in the pump chamber 60. G is stirred. As a result, the contents of the stock solution G can be sufficiently stirred and mixed, so that it can also be used for stock solutions that are easily separated, such as a stock solution containing powder. The stock solution G inside the container body 22 is also stirred at the same time.
[0040]
Next, by pushing the push button 64a and performing the ejection step S2 of FIG. 7, the stock solution can be sent to the refill container side, and further, the pressure release step S3 and the suction step S4 are performed in order by pushing and releasing the push button. . Also in this case, since the check valve 24 is provided in the adapter 4 or the like as described above, the stock solution does not flow backward.
[0041]
In the embodiments of the adapters 5 and 5A shown in FIGS. 3 and 4 and the container 3A with a pump shown in FIG. 5, both of them are provided with ball valve type check valves 24 and 24B. It may be a check valve.
[0042]
In the above-described embodiment, a hand-pumped container with a pump is used as the stock solution replenishing device, but a container with a motor-driven pump may be used. In this case, manual pump operation is not necessary, so that the stock solution replenishment work to the refill container is facilitated. Further, the stock solution replenishing device may be an aerosol-type stock solution replenishing device in which a propellant is filled in the container body together with the stock solution or isolated from the stock solution. Also in this case, since the stock solution can be replenished to the refill container with the pressure of the propellant, no pump operation is required and replenishment work is easy.
[0043]
FIG. 8 shows an aerosol-type stock solution replenishing device 65. This is composed of a double aerosol product (multi-chamber container) 66, a tube 4 connected to a push button 68 attached to a stem 67 of the valve, and an adapter 5 connected to the tip of the tube 4. The tube 4 and the adapter 5 may be the same as those shown in FIG. As the double aerosol product 66, for example, as shown in FIG. 9, the container body 69, the valve 70 attached to the upper end thereof, and the flexibility having the upper end portion sandwiched between the container body 69 and the valve 70 are provided. A conventionally known inner bag type comprising the inner bag 71 is used. The inner bag 71 is filled with a stock solution G, and a compressed gas E2 is filled between the inner bag 71 and the container body 69.
[0044]
This is done by removing the push button 11 of the refill container 1 as shown in FIG. 1 and connecting the adapter 5 and pushing the push button 68 of the double aerosol product 66 while pushing the adapter 5 and opening the valve of the refill container. G can be filled into the refill container with the pressure of the compressed gas E2. Therefore, handling is easier. When the push button 68 is configured to be exchangeable with a normal push button having a nozzle or a spout, for example, the stock solution is sprayed directly from the double aerosol product 66 at home, and the refill container is filled with the stock solution when going out. It can also be used in the form of carrying it.
[0046]
FIG. 10 shows a refill container that is easier to manufacture than the refill container of FIG. The refill container 1 includes a bottomed cylindrical synthetic resin container body 7 and a valve 9 bonded to the upper end opening thereof by an adhesive or heat bonding. A push button 11 is detachably attached to the stem 10 of the valve. Furthermore, the tip of a cylinder (syringe) 12 of a so-called disposable type syringe is fitted and inserted into the lower end of the housing of the valve 9 and bonded and fixed with an adhesive or the like. A protrusion 73 is provided in the vicinity of the peripheral edge of the lower surface of the piston 13 slidably accommodated in the cylinder 12. The protrusion 73 is for communicating the first chamber 19 and the second chamber 20 when the piston 13 comes to the lower end.
[0047]
That is, when the compressed gas E is filled into the cylinder 12 through the valve 9 as shown in FIG. 11b from the state before filling shown in FIG. 11a, the piston 13 descends and the protrusion 73 comes into contact with the bottom surface of the container body 7. In that case, since the protrusion 73 is provided eccentrically, the piston 13 is inclined. Thereby, the upper and lower sides of the piston 13 communicate with each other, and the compressed gas E is also filled in the second chamber 20.
[0048]
Next, when the compressed gas E above the piston 13 in the cylinder 12 is extracted via the valve 9 as shown in FIG. 12 a, the piston 13 rises to the upper end of the cylinder 12. In this state, since the inner surfaces of the piston 13 and the cylinder 12 are sealed, the compressed gas E in the second chamber 20 does not escape. The refill container 1 is usually sold in this state. However, you may sell in the state which filled the stock solution in the refill container beforehand.
[0049]
As shown in FIG. 12 b, the user pressurizes and fills the cylinder 12 with the stock solution G from the valve 9. The operation is performed using a stock solution replenisher. In that case, care is taken so that the piston 13 does not reach the lower end of the cylinder 12. By this filling, the compressed gas E in the second chamber 20 is somewhat compressed. After filling the stock solution G in this way, the adapter of the stock solution replenishing device is removed and the push button 11 is attached as shown in FIG. The stock solution G can be ejected by pushing the push button 11. In FIGS. 10 and 12b, only the portion of the stock solution G is hatched for easy understanding.
[0050]
In the embodiment of FIG. 1 and the like, the adapter 5 is attached to the tip of the tube 4 and the refill container 1 and the stock solution container are connected and filled with the tube, but as shown in FIG. The adapter 5 may be provided on the handle for operating the pump of the container 3, and the refill container 1 may be directly connected to the container 3 with a pump without using a tube. In place of the container 3 with the pump, an aerosol product as shown in FIG. 9 can be adopted and an adapter can be provided on the push button. In the embodiment of FIG. 13, the refill container 1 is turned upside down and connected to the outlet 5 of the stock solution container, that is, the adapter 5 provided on the handle of the pump. Therefore, by pushing down the refill container 1, the valve and pump of the refill container 1 can be operated simultaneously, and the refill container 1 can be filled with the stock solution. Even when the aerosol product as shown in FIG. 9 is adopted, the valve of the refill container and the valve of the aerosol product can be simultaneously opened and closed by pushing the refill container.
[0051]
FIG. 14 a shows another embodiment of the push button of the refill container 1. This push button 11A is provided with a supply port 75 for connecting to the adapter of the stock solution replenisher at the upper end. The passage 76 that communicates with the stem 10 of the valve 9 can be switched by the three-way cock 80 so that it can selectively communicate with either the passage 78 that communicates with the nozzle 77 or the passage 79 that communicates with the supply port 75. I have to. The supply port 75 is provided with a check valve 81 that allows the flow from the outside to the inside but stops the flow in the reverse direction. The check valve 81 can be composed of a ball 82 and a spring 83, for example.
[0052]
In the refill container 1, as shown in FIG. 14 b, the three-way cock 80 is switched so that the stem 10 and the nozzle 77 communicate with each other to block the supply port 75. In this state, the stock solution in the refill container 1 can be ejected from the nozzle 77 by pressing the push button 11A. On the other hand, when filling the stock solution from the stock solution replenishing device, as shown in FIG. 14C, the three-way cock 80 is switched to connect the stem 10 and the supply port 75, and the passage 78 on the nozzle 77 side is shut off. In that case, since there is the check valve 81, the stock solution remaining inside does not spout to the outside. Next, an adapter of the stock solution supply device is connected to the supply port 75 to fill the refill container 1 with the stock solution. Thus, in this embodiment, there is an advantage that the stock solution can be refilled without removing the push button 11A.
[0053]
The push button 11B shown in FIG. 15a is provided with a lid 85 for closing the supply port 75 so as to be rotatable by a support shaft 85a. Then, instead of the above-described three-way cock 80, a slide-type switching valve (spool) 86 shown in FIG. 15B replaces the passage 76 communicating with the stem 10 with the passage 78 communicating with the nozzle 77 or the passage 79 communicating with the supply port 75. It is configured to selectively communicate with either one. Further, the spool 86 moves backward when the lid 85 is closed to communicate the stem 10 and the nozzle 77, and moves forward when the lid 85 is opened to communicate the stem 10 and the supply port 75 with respect to the lid 85. Link 87. In this case, the area around the supply port 75 does not become dirty, and when connected to the stock solution replenishing device, it is possible to prevent erroneous operation due to forgetting to switch the three-way cock. In addition, in the push button 11A of FIG. 14a, a lid that rotates between the upper side and the front side of the push button 11A using the three-way cock 80 as a support shaft may be provided. In that case, the three-way cock can be operated by opening and closing the lid.
[0054]
The refill container 1 shown in FIG. 16 is provided with a fixed quantity ejection mechanism in the valve 9 of the refill container of FIG. Such a refill container 1 is suitably used for injecting an active ingredient that imparts taste, medicinal effect and the like into the oral cavity one by one. In the valve 9 of FIG. 16, a bottomed cylindrical guide bush 88 is accommodated in the housing 15 with a gap, and a bottomed cylindrical flexible tank 89 is provided between the housing 15 and the guide bush 88. Is housed. The lower end of the stem 10 protrudes downward through a hole 90 formed in the bottom of the guide bush 88. The lower end of the tank 89 is a lower seal (lower valve) 91 that is closed when the lower end of the stem 10 is fitted. The bottom of the tank 89 seals between the housing 15 and the guide bush 88. A communication hole 92 communicating with the inside of the container body 7 is formed on the side wall of the housing 15. A communication hole 93 that communicates with the inside of the tank 89 is also formed in the side wall of the guide bush 88. A plurality of protrusions or ribs 94 project radially from the inner wall of the tank 89 or the outer wall of the guide bush 88. The ribs 94 are shape stabilizers for stabilizing the shape of the tank 89 when the tank 89 is bent inward. The tank 89 can be formed of rubber, elastomer, soft synthetic resin, or the like.
[0055]
Since the inside of the guide bush 88 and the second chamber of the cylinder 12 communicate with each other until the push button 11 is pushed, the pressure inside and outside the tank 89 is balanced and spreads outward as shown in FIG. It has a shape. When the push button 11 is pushed in from this state, the lower end of the stem 10 is fitted into the lower seal 91 and the space between the cylinder 12 and the guide bush 88 is sealed. When the push button 11 is further pressed, the small hole 10a at the top of the stem 10 communicates with the inside of the guide bush 88, and the stock solution in the guide bush 88 and the tank 89 is ejected to the outside through the stem and the spout of the push button. When the pressure in the guide bush 88 is reduced to the same level as the atmospheric pressure, the ejection stops. Therefore, the amount of injection at one time is limited by the volume of the guide bush 88 and the tank 89, and a quantitative ejection action is achieved.
[0056]
At the time of the above jetting action, the outside of the tank 89 is the same as the internal pressure in the container through the communication hole of the housing, and the inside of the tank 89 is the same pressure as in the guide bush 88. Therefore, the tank 89 elastically contracts and deforms due to the pressure difference, and the pressure drop in the guide bush 88 is delayed by that amount. That is, the tank 89 functions as an accumulator (pressure accumulator), and a relatively stable quantitative ejection operation is achieved even when the volume of the guide bush 88 is small. In addition, the radial rib 94 between the tank 89 and the guide bush 88 stabilizes the shape when the tank 89 is contracted, so that a more stable quantitative ejection action is achieved.
[0057]
In the above-described quantitative ejection mechanism, the guide bush 88 can be considered as a normal housing, and in this case, the housing 15 can be considered as a protective cover for protecting the tank 89. Therefore, it can be said that the tank 89 is a fixed quantity ejection mechanism provided outside the housing or outside the valve.
[0058]
The refill container 1 of FIG. 17 is the same as the refill container of FIG. 16 in that a lower seal 91 that is closed by the lower end of the stem 10 is provided at the lower part of the housing 15, but a pipe line 96 is provided outside the housing 15. It is different in that the tank 89 is connected via the via. The tank 89 is provided with a main body 98 in which an annular vacant space 97 having an arc-shaped cross section is formed at the center of a side surface, a cylindrical body 99 such as rubber fitted around the main body, and an outer side thereof. Cover 100. The quantitative ejection action of this is the same as in the case of the refill container of FIG. That is, after the push button 11 is pushed and the lower part of the stem 10 closes the lower seal 91, the stock solution in the housing 15 and the tank 89 is subjected to a pressure action based on the original internal pressure and the elastic deformation of the cylindrical body 99 of the tank 89. Squirt outside. Similar to the refill container of FIG. 16, this can also be used for ejecting a chemical into the oral cavity.
[0059]
【Example】
The refill container of FIG. 11a (cylinder volume 6 ml) was filled with compressed air until the pressure reached 0.15 MPa as shown in FIG. 11b, and then the compressed air in the cylinder was discharged as shown in FIG. 12a. Further, it was connected to a stock solution replenisher and filled with 5 ml of emulsion as shown in FIG. 12b. The pressurizing pressure of the stock solution replenisher was 0.3 MPa. Then, a push button was attached to the valve, and the whole amount of the emulsion was ejected. Further, in the same manner as described above, when the filling of the emulsion and the ejection were repeated 10 times, the ejection could be repeated without any delay.
[Brief description of the drawings]
FIG. 1 is a partially sectional side view showing an embodiment of an in-use filling system of the present invention.
FIG. 2 is a cross-sectional view showing an embodiment of the refill container of the present invention.
FIG. 3 is a cross-sectional view showing an embodiment of an adapter according to the present invention.
FIG. 4 is a cross-sectional view showing an embodiment of an adapter according to the present invention.
FIGS. 5a and 5b are cross-sectional views of the main part showing one embodiment of a container with a pump according to the present invention and its operating state, respectively.
FIG. 6 is a cross-sectional view of an essential part showing still another embodiment of a pump-equipped container according to the present invention.
7 is an operation state explanatory view of the pump-equipped container of FIG. 6. FIG.
FIG. 8 is a side view of an essential part showing another embodiment of the stock solution replenishing apparatus according to the present invention.
9 is a cross-sectional view showing a double aerosol product in the stock solution replenishing device of FIG.
FIG. 10 is a cross-sectional view showing still another embodiment of a refill container according to the present invention.
11a and 11b are explanatory views showing a procedure for filling the refill container of FIG. 10 with compressed gas.
12a and 12b are explanatory views showing a procedure for discharging a compressed gas from the refill container in the state of FIG. 11b and filling the stock solution.
FIG. 13 is a front view showing still another embodiment of the in-use filling system of the present invention.
FIG. 14a is a sectional view showing another embodiment of the push button used in the refill container of the present invention, and FIG. 14b and FIG. 14c are explanatory views of the operation state thereof.
FIG. 15a is a cross-sectional view showing still another embodiment of the push button used in the refill container of the present invention, and FIG. 15b is an enlarged perspective view of an essential part thereof.
FIG. 16 is a cross-sectional view of an essential part showing still another embodiment of the refill container of the present invention.
FIG. 17 is a cross-sectional view of an essential part showing still another embodiment of the refill container of the present invention.
[Explanation of symbols]
A When filling system
1 Refill container
2 Stock solution replenisher
3 Container with pump
4 tubes
5 Adapter
7 Container body
9 Valve
11 Push button
12 cylinders
13 Piston
19 Room 1
20 Room 2
G Stock solution
E Compressed gas
21 Container body
22 Pump
24 Check valve
5A adapter
24A check valve
3A container with pump
24B Check valve
11A push button
11B push button
89 tanks
91 Bottom seal

Claims (15)

A translucent container body, an aerosol valve attached to the opening of the container body, a translucent cylinder connected to the inner side of the aerosol valve so that the lower end side communicates with the inside of the container body, and A piston that is slidably fitted in the cylinder, and the upper part of the piston in the cylinder is filled with the stock solution, and the lower part of the piston in the cylinder and the compressed gas is filled between the cylinder and the container body, A refill container configured to tilt when the piston reaches the lower end of the cylinder. The refill container according to claim 1, wherein a protrusion is eccentrically provided on a lower surface of the piston. The refill container according to claim 1, wherein the container body is made of a synthetic resin having a bottomed cylindrical shape, and an aerosol valve is bonded to an upper end opening thereof. The refill container according to claim 1, wherein a fixed amount injection mechanism capable of injecting a certain amount is provided in the aerosol valve. The refill container according to claim 1, wherein a push button for opening and closing the aerosol valve is attached to the aerosol valve. The refill container according to any one of claims 1 to 5,
A stock solution replenishing device for filling the stock solution in the cylinder of the refill container,
The in-use filling system, wherein the stock solution replenishing device comprises a stock solution container for containing the stock solution, a means for pressurizing the stock solution, and a connecting means detachably connected to the outlet side of the aerosol valve of the refill container. . The in-use filling system according to claim 6, wherein the pressurizing means is a pump attached to the mouth of the stock solution container. In order to pressurize the first chamber, the pressurizing means includes a partition wall that variably isolates the interior of the stock solution container into at least two chambers, a valve that communicates / blocks the first chamber filled with the stock solution, and the outside. The in-use filling system according to claim 6, comprising compressed gas filled in another chamber. The in-use filling system according to claim 6, wherein the stock solution replenishing device is provided with a check valve for blocking back flow from the refill container side. A container body, an aerosol valve attached to the opening of the container body, a cylinder connected to the inner side of the aerosol valve so that a lower end side communicates with the inside of the container body, and a slidably fitted in the cylinder And a refill container manufacturing method configured such that when the piston reaches the lower end of the cylinder, the piston is inclined.
The cylinder is filled with compressed gas through the aerosol valve, so that the piston descends in the cylinder, the piston contacts the bottom surface of the container body, the piston tilts, and the upper and lower sides of the piston communicate with each other. Filled in the space between the body and the cylinder,
Thereafter, the compressed gas in the cylinder is discharged through the aerosol valve, whereby the piston rises in the cylinder, and the piston seals the upper and lower sides of the piston in the cylinder. The method for manufacturing a refill container according to claim 10, wherein a protrusion is eccentrically provided on the lower surface of the piston, the lower surface of the piston contacts the bottom surface of the container body, and the piston is inclined. The method for producing a refill container according to claim 10, wherein after the piston moves up in the cylinder and the piston seals the upper and lower sides of the piston in the cylinder, the stock solution is pressurized and filled into the cylinder from the aerosol valve. A container body, an aerosol valve attached to the opening of the container body, a cylinder connected to the inner side of the aerosol valve so that a lower end side communicates with the inside of the container body, and a slidably fitted in the cylinder A method of manufacturing a refill container having a piston,
Insert the cylinder and piston into the container body with a flat bottom,
Attach an aerosol valve to the opening of the container body,
The cylinder is filled with compressed gas via its aerosol valve, which It is lowered in the cylinder, the piston contacts the bottom surface of the container body, communicates with the top and bottom of the piston, and the compressed gas is filled in the space between the container body and the cylinder,
Compress the compressed gas in the cylinder through the aerosol valve,
Then, the manufacturing method of the refill container which forms a curved protrusion in the center of the bottom part of the container body so as to face the cylinder and prevent the compressed gas from being mixed into the cylinder when the piston descends to the lower end. The refill container is provided on a piston and includes a piston seal that seals the top and bottom of the piston,
When the piston contacts the flat bottom surface of the container body, the piston seal is positioned below the lower end of the cylinder, and after the curved protrusion is formed at the bottom center of the container body, when the piston descends to the lower end, The method for manufacturing a refill container according to claim 13, wherein the piston seal is located above the lower end of the cylinder. The method for producing a refill container according to claim 13, wherein after the curved protrusion is formed, the stock solution is pressurized and filled into the cylinder from the aerosol valve.

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