JPS63165126A - Manufacture of formable liquid product - Google Patents

Abstract

PURPOSE:To make it possible to highly efficiently manufacture foamable liquid product in large quantities by a method wherein pressurized foamable liquid is made by agitating stock liquid or stock liquid and low boiling substance, which are changed in a large-volume pressure vessel, under the condition that the pressure in the pressure vessel is gradually increased by filling with insoluble gas and, after that, the resultant pressurized foamable liquid is filled in small containers. CONSTITUTION:By opening the upper part 13 of a pressure vessel 1, stock liquid L for whipped cream is changed in the pressure vessel 1. After the upper part 13 is closed, depressurization is applied through a gas exhaust port 6 in order to discharge the air out of the vessel 1. After that, while agitating blades 5 are rotated for agitation, nitrogen gas is blown through a gas lead-in port 7 out of a bubbling pipe 71 in the stock liquid L so as to bring the interior of the vessel 1 into the elevated pressurized state so as to turn the stock liquid L into pressurized whipped cream. Finally, the resultant cream is filled into a small containers such as the partition wall type aerosol container or the like. As a result, by using a vessel with large volume as the pressure vessel, the highly efficient manufacture of product in large quantities becomes possible.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Field of Application] The present invention relates to a method of manufacturing a foamable liquid product.

[Conventional technology]

At present, the main foaming liquid products are co-foaming products, where the foam is obtained directly from the container, e.g. as embodied in aerosol products for whipped cream;
Also known are so-called post-foaming products, which foam under specific conditions after being discharged from the container and are embodied, for example, in aerosol products for facial cleansing creams or shaving creams.

The above-mentioned simultaneous foaming product, for example, an aerosol product for whipped cream, can be produced by directly filling an aerosol container with a whipped cream stock solution together with carbon dioxide gas dissolved in the stock solution and insoluble nitrogen gas, and then shaking the product. Manufactured.

The content of this product is a state in which carbon dioxide gas is dissolved in the stock solution for whipped cream, and it is injected into the atmosphere from an aerosol container mainly by the injection force of nitrogen gas, thereby removing the carbon dioxide gas dissolved in the stock solution. Vaporization forms bubbles, thereby forming a foam.

In addition, post-foaming aerosol products, such as those for facial cleansing creams, are produced by adding a low-boiling point substance such as isopenkune to the stock solution in liquid form to form a gel, which is then filled into an aerosol container with a gas for injection. be done. The contents of this product are low boiling point substances dissolved in the stock solution, and when the product is injected from the aerosol container with a propellant gas and touches the human body, the low boiling point substances dissolved in the stock solution are vaporized by body heat. bubbles are formed, thereby forming a foam.

[Problem that the invention seeks to solve]

However, in the conventional methods for producing foamable liquid products as described above, there is a problem in that a foamable liquid product having sufficient properties cannot be produced in large quantities with high efficiency.

For example, in the case of simultaneous foaming products, it is necessary to use a gas that is soluble in the stock solution, which limits the type of gas that can be used, and in the case of whipped cream, which is a food aerosol product, carbon dioxide gas must be used. However, there are problems in that the whipped cream obtained becomes sour and loses its original flavor, and that it is not possible to obtain whipped cream with a sweet taste.

Further, in the case of post-foaming products, although it is necessary to dissolve a low-boiling point substance in the stock solution, there is a problem in that it is very difficult to dissolve a large amount of a low-boiling point substance.

An object of the present invention is to solve the above-mentioned problems and provide a method that can produce a foamable liquid product with excellent properties in large quantities and with high efficiency.

Means for Solving the Problem c] The method for producing a foamable liquid product of the present invention includes placing a stock solution or a stock solution and a low-boiling point substance in a pressure-resistant container, and filling the pressure-resistant container with an insoluble gas. This method is characterized by gradually increasing the pressure within the pressure-resistant container and stirring the stock solution to create a pressurized foamable liquid, which is then filled into a small container.

According to this method, the pressure in the pressure container is increased and the stock solution is stirred, so that by using a gas insoluble in the stock solution as a bubble forming agent, the insoluble gas is uniformly dispersed in the stock solution as fine bubbles. By using a low boiling point substance as a bubble forming agent, a large amount of low boiling point substance can be easily dissolved in the stock solution, and as a result, by using a large capacity pressure vessel, A foamable liquid product with excellent properties can be produced in large quantities with high efficiency.

Examples of the present invention will be described below.

FIG. 1 shows a device used to carry out the present invention. In FIG. 1, 1 is a pressure-resistant container, and this pressure-resistant container 1 is provided with a lower portion 11 and a flange 12 so that it can be opened and closed with the lower portion 11. and an upper portion 13. A motor 3 is provided on the upper part 13 of the pressure vessel 1 via a bracket 2, and the drive shaft of the motor 3 is a rotary drive shaft that extends through the wall of the upper part 13 of the pressure vessel 1 in an airtight manner. 4, and a stirring blade 5 is provided at the inner end (lower end) of this rotary drive shaft 4.

The upper part 13 of the pressure vessel 1 is further provided with a gas outlet 6, a gas introduction lower, and a pressure gauge 8, and the lower part 11 is provided with a valve 11119 and a discharge valve 10. In the gas introduction lower part, a bubbling pipe 7 extends downward inside the pressure-resistant container l and immerses into the raw liquid tank.
1 is connected.

In the present invention, using such an apparatus, a desired foamable liquid is produced by using a gas that is insoluble in the stock solution as a bubble forming agent, or using a low-boiling point substance, and stirring the stock solution under pressure with the insoluble gas. Get the product.

Specifically, when manufacturing an aerosol for whipped cream, for example, the upper portion 13 of the pressure-resistant container 1
, put the stock solution for whipped cream made according to the desired recipe into the pressure container 1 to about half its height, close the upper part 13, and apply reduced pressure through the gas outlet 6. The air inside the pressure vessel 1 is removed, and then,
The motor 3 is driven to rotate the stirring blades 5 to stir the stock solution while at the same time nitrogen gas is gradually introduced into the pressure vessel 1 via the gas introduction lower, whereby nitrogen is introduced into the stock solution from the bubbling vibrator 71. The pressure inside the pressure container 1 is increased by blowing out gas to finally reach a high pressure state, and the stock solution is made into pressurized whipped cream by stirring under such high pressure. Then, this pressurized whipped cream is filled into a small container such as a septum-type aerosol container, thereby producing an aerosol for whipped cream.

In the above, the formulation of the stock solution for whipped cream is not particularly limited, but examples are as follows.

[Prescription example]

Monoglyceride 3.0-3.5% by weight Propylene glycol ester 0, 15-0.3% by weight Avicel or CMG O. 4-0.6% by weight Sodium caseinate 0.2-0.5% by weight Non-fat emulsified solids 4.4% by weight Sand
Sugar 20% by weight Sodium hexametaphosphate 0.1% by weight Vegetable oil fat content
25% water by weight
The amount of nitrogen gas introduced into the pressure container 1 depends on the capacity of the pressure container 1, the formulation of the stock solution for whipped cream, the stirring means, etc. , especially 6-8
It is preferable to carry out the treatment until kg/cI12 or more.

The temperature of the stock solution in the pressure-resistant container 1 is not particularly limited, but may be, for example, 5 to 15°C.

Various types of stirrers can be used to stir the stock solution, such as a whisk-like stirrer made of metal wire, a stirrer with screw-shaped stirring blades, etc. Can be done. However, it is not preferable to apply too large a shearing force. The rotational speed of the stirrer may be appropriately selected depending on the type of stirrer used, etc. (eg, 150 to 350 rpm).

Furthermore, the same effect can be obtained by irradiating ultrasonic waves from outside the pressure vessel 1 instead of using a mechanical stirrer.

FIG. 2 schematically shows an example of a dispensing device for filling a small container such as an aerosol container with the pressurized foamable liquid in the pressure container 1. In this dispensing device, a quantitative sampling container 20 with a capacity corresponding to the small container V to be filled is provided, and an outlet 10 of the pressure container 1 is connected to the upper inlet of the container via a first valve 21. At the same time, a pressurizing pump 23 is connected via a second valve 22, which applies a pressure P2 higher than the pressure P1 in the pressure container 1 to the pressurized foaming liquid in the quantitative sampling container 20. A small container V is detachably connected to a discharge adapter 26 provided at the lower outlet of the container 20 via a third valve 24. A buffer-type high-pressure inert gas source 25 is further connected to the small container (2) to maintain the inside of the small container V at a pressure lower than the pressure P2.

According to the dispensing device having such a configuration, the second valve 22
and the first valve 2 with the third valve 24 closed.
1 is opened, the pressurized foamable liquid in the pressure container 1 is put into the quantitative sampling container 20, and the first valve 21 is closed, whereby a predetermined amount of the pressurized foamable liquid is dispensed into the quantitative sampling container 20. It will be done. On the other hand, a small container V is connected to the discharge adapter 26, and the inside of the small container V is heated by high-pressure inert gas S2S to the pressure PI in the pressure-resistant container 1 or a pressure B slightly higher than that (but lower than the pressure P8). In this state, the second valve 22 is opened to apply the pressure of the pressurizing pump 23 to the pressurized foaming liquid in the quantitative sampling container 20, and the third valve 24 is opened, the quantitative sampling container is 2
The pressurized foamable liquid in 0 is injected into the small container V by the pressure of the pressurizing pump 23, and at the same time, the high pressure gas in the small container V is expelled to high pressure inert gas B25. Incidentally, when the small container (2) is a partition wall type aerosol container, the above-mentioned action is performed through the partition wall. In this way, the pressurized foamable liquid is filled into the small container V, but during this filling process, the pressurized foamable liquid is always kept under a high pressure state, so it will not foam during the process. .

As described above, when dispensing the pressurized foamable liquid prepared in the pressure-resistant container 1 into a small container, the pressure inside the small container is kept at a state equal to or higher than the pressure inside the pressure-resistant container 1. In this state, the pressurized foamable liquid from the pressure container 1 can be injected by pressure. Therefore, in order to dispense into a small container, the pressure foamable liquid must be brought to a lower pressure than in the pressure container 1. For example, in the example shown in FIG. 2, instead of the first pulp 21 and the second pulp 22, a dispensing device that does not dispose of the first pulp 21 and the second pulp 22 may be used, and its specific configuration is not limited. Alternatively, a pressurized foaming method may be used, in which a small container whose opening is closed with a thick rubber membrane and a discharge end made of a needle-like tube instead of the discharge adapter 26 may be used. It is also possible to use a liquid dispenser in combination.

According to the method described above, the stock solution for whipped cream is stirred in the pressure-resistant container 1 in an environment where high-pressure nitrogen gas exists, so minute bubbles of nitrogen gas are uniformly formed in the stock solution. Pressurized whipped cream in a mixed state is formed, and this pressurized whipped cream is filled into an aerosol container 20 to form an aerosol product,
Therefore, since the content of this aerosol product is the above-mentioned pressurized whipped cream, when it is ejected into the atmosphere, the nitrogen gas microbubbles inside expand and become large bubbles due to the decrease in surrounding pressure. As a result, desired whipped cream can be obtained.

Since the stock solution is stirred under high pressure with nitrogen gas, the nitrogen gas becomes dispersed in the stock solution as extremely small bubbles, and as a result, it is possible to uniformly disperse a large amount of insoluble gas into the stock solution. This makes it possible to obtain sufficiently good foamability. Furthermore, by adjusting the final pressure of the nitrogen gas introduced into the pressure container 1, the degree of overrun can be controlled and whipped cream with a desired overrun can be obtained. To explain specifically, for example, as a stock solution for whipped cream, the bulk density is 1.
．． It was produced by using oOL and driving a so-called bubbling δ type stirrer at a rotational speed of 20 Or, p, vb, and changing the final pressure by introducing nitrogen gas. The bulk density of the whipped cream obtained from the aerosol product was as shown in Table 1. Note that the unit of pressure is (kg/cm'').

Table 1 Furthermore, since insoluble gases can be used as foam-forming agents, the range of choice is wide and the preferred gases can be used in the stock solution. It is not necessary to use gas, and by using nitrogen gas, whipped cream with good flavor can be obtained. This insoluble gas is not particularly limited, and any gas can be used as long as it is insoluble in the stock solution.For example, in order to obtain the above-mentioned whipped cream, in addition to nitrogen gas, argon gas or A mixture of these gases can also be used.

The means for introducing the insoluble gas into the pressure vessel is free, and in some cases it may be sufficient to simply introduce it into the upper space of the pressure vessel instead of blowing it into the original IL.

Further, in the present invention, a low boiling point substance can be used as a foam forming agent, thereby making it possible to obtain a so-called post-foamed foamable liquid product.

For example, instead of the above-mentioned whipped cream stock solution, a facial cleansing cream stock solution and a low boiling point substance such as isopentane are placed in a pressure-resistant container, and nitrogen gas is gradually introduced into the pressure-resistant container while stirring. The pressure inside the container is increased to finally reach a high pressure state, thereby obtaining a pressurized solution consisting of the stock solution and a low boiling point substance. This pressurized solution is then filled into a small container such as a septum-type aerosol container to produce an aerosol product for facial cleansing cream.

In the above, the formulation of the facial cleansing cream stock solution is not particularly limited, but examples are as follows.

[Prescription example]

Sodium coconut oil fatty acid N-acyl-glutamate 24.00% by weight glycerin
8.00% by weight denatured ethanol
4.00% by weight Ranogen C 1,00% by weight Stearic acid 2.50% by weight Myristic acid jetanolamide 2.00% by weight Stearyl glycyrrhetinate 0.05% by weight Cholesterol
0.10% by weight Polyoxyethylene heptyl ether 0.20% by weight Potassium laurate 5.00% by weight Aqualyzer E, JO, 10% by weight Polyethylene glycol 20000 2.00% by weight Fragrance 0.60% by weight Dichlorotetra Fluoroethane 4.00% by weight purified water
Of course, foamable liquid products for various purposes can be similarly produced by changing the composition of the stock solution.

As the low boiling point substance, for example, Freon 114, n-pentane, etc. having a boiling point of 5 to 36° C. can be preferably used. The proportion of this low boiling point substance is not particularly limited, but is usually 0.2 to 3.0% by weight.

The introduction of gas into the pressure vessel may be appropriately selected depending on various conditions.

The temperature inside the pressure container is not particularly limited, but may be, for example, 5 to 15°C.

In addition, dispensing into small containers can be performed using the dispensing device shown in Figure 2 or other devices, but the pressurized foaming liquid that is foamed after this cannot be simply placed under reduced pressure. Since it does not foam, the conditions for normal dispensing are relaxed.

According to the method described above, the stock solution and the low-boiling point substance are stirred under high pressure in the pressure-resistant container, so that a pressurized liquid in which a large amount of the low-boiling point substance is dissolved in the stock solution is formed.
This aerosol product is filled into an aerosol container and made into an aerosol product.When the contents are squirted out and taken into the hand, the low boiling point substance is vaporized by the body heat of the person, forming bubbles, resulting in foaming. You can get cleansing cream etc.

When a low-boiling substance is used as a bubble-forming agent in this manner, the stock solution is stirred together with the low-boiling substance while pressurized in a pressure-resistant container, so that a large amount of the low-boiling substance can be dissolved in the stock solution.

Note that when a low boiling point substance is used as a bubble forming agent in this way, the type of gas and the means for introducing the gas for obtaining high pressure are completely free.

In the present invention, as a small container for dispensing from a pressure-resistant container, for example, a piston-type aerosol container or a bag-type aerosol container can be suitably used in the case of an aerosol product. However, in the present invention, it is also possible to use a small container other than an aerosol container and to dispense into this.

〔Effect of the invention〕

According to the method for manufacturing a foamable liquid product of the present invention, as described above, since the pressure in the pressure container is increased and the stock solution is stirred, the insoluble gas is used as a bubble forming agent in the stock solution. It is possible to obtain a state in which fine bubbles are uniformly dispersed in the stock solution, and by using a low-boiling point substance as a bubble-forming agent, a large amount of the low-boiling point substance can be easily dissolved in the stock solution, and as a result,
By using a large-capacity pressure container, a foamable liquid product with excellent properties can be produced in large quantities with high efficiency.

[Brief explanation of the drawing]

FIG. 1 is an explanatory cross-sectional view showing an apparatus used for carrying out the present invention, and FIG. 2 is an explanatory view schematically showing an example of means for filling a small container with a pressurized foamable liquid in a pressure-resistant container. It is. ■...Pressure container 11...Lower part 12.
... Flange 13 ... Upper part 2 ... Bracket 3 ... Motor 4 ... Rotation drive shaft 5 ... Whip stirring blade 6 ... Gas discharge port 7 ... Gas introduction lower 1.
...bubbling vibe 8...pressure gauge 9...legs
10... Outlet L... Undiluted solution
V...Small container 20...Quantitative collection container 21
...First valve 22...Second valve 23
... Pressure pump 24 ... Third valve 25.
...High pressure inert gas source 26...Discharge adapter

Claims (1)

[Claims] 1) A stock solution or a stock solution and a low-boiling substance are placed in a pressure container, and the pressure in the pressure container is gradually increased by filling the pressure container with an insoluble gas. 1. A method for producing a foamable liquid product, which comprises: stirring to create a pressurized foamable liquid, and filling this into a small container. 2) The method for producing a foamable liquid product according to claim 1, wherein the pressurized foamable liquid is in a state in which an insoluble gas is finely dispersed in a stock solution. 3) Claim 1, characterized in that the pressurized foaming liquid is in a state in which a low boiling point substance is dissolved in the stock solution.
A method for producing a foamable liquid product as described in Section 1. 4) Pressurization is achieved by taking out a portion of the pressurized foamable liquid in the pressure-resistant container under pressure and injecting it into a small container maintained at a pressure equal to or higher than the pressure in the pressure-resistant container. 4. A method for producing a foamable liquid product according to claim 2 or 3, characterized in that the foamable liquid is filled into a small container.