JP2011088080A - Microbubble-containing composition and microbubble generator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To enable easier use of microbubbles, to solve a problem that conventionally an oxygen gas cylinder, a nitrogen gas cylinder, and a carbon dioxide gas cylinder are required, thereby occupying a space, and to allow use of purchased dry ice when carbon dioxide microbubbles are used in the home. <P>SOLUTION: A means for controlling evaporation of a solid or liquid at a gas pressure near atmospheric pressure is installed, whereby a microbubble generator using suction by an existing vortex pump can be used. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

The present invention mainly relates to a composition for stimulating a living body surface (skin) and activating a surface tissue, and an apparatus for producing the composition.

  The composition is a so-called “microbubble”, in which the gas forming the bubble is the atmosphere, for example nitrogen (N2) or oxygen (O2) or carbon dioxide (CO2), in particular the atmosphere and N2 It has been found that if the composition of O2 and CO2 is different, it has properties different from those of normal bubbles and has a great influence on the surface of the living body (skin).

  This “microbubble” is a low-concentration type: there is a distribution peak around 30 μm in diameter, and the bubble concentration is about several hundreds / mL. It looks like a little cloudy water. And high concentration type: There is a peak of bubble distribution around 10μm, and the number of bubbles is more than several thousand / mL. It looks like milk.

  The composition of the present invention contains these “microbubbles”, and these bubbles stimulate the surface of the living body (skin) and activate the surface tissue, thereby providing a health promoting effect when applied to the human body. .

  Here, the empirical difference between the two types of “microbubbles”: low concentration type (30 μm) and high concentration type (10 μm) is generally different from the various effects given by the high concentration type (10 μm). It is much larger than that of (30μm).

  Therefore, when the present invention is carried out, the high concentration type (10 μm) is similarly effective.

  A technique for generating high-concentration type (10 μm) microbubbles is described in Patent Document 1, for example.

  On the other hand, Patent Literature 2 and Patent Literature 3 describe cell culture techniques of a low concentration type (30 μm) or a lower (millimeter scale) type having a larger bubble diameter.

  Patent Document 4 and Patent Document 5 disclose the generation of microbubbles by gas obtained by vaporization (sublimation) of “solidified gas (dry ice)”, which is the same concept as the present invention. However, it is doubtful whether the above-mentioned fine particle size bubbles that fall into the microbubble category are produced effectively.

  On the contrary, the description of the gas suction in Patent Document 1 uses a vortex pump that performs gas suction at atmospheric pressure.

These known techniques are the background of the present invention.
Japanese Patent No. 3620797, “Microbubble generator”, IPMS Japanese Patent No. 2762372 “Microbubble Generator” Komatsu Ltd. Japanese Patent Publication No. 5-60353 “Culture method and apparatus by aeration in liquid” Hitachi, Ltd. Published Patent Publication No. 2005-261888 “Microbubble medical device and health device using carbon dioxide gas” Light Creation Laboratory Published Patent Publication No. 2005-245990 “Carbonated spring medical device and health device using dry ice” Light Creation Laboratory

  An object of the present invention is to use microbubbles more easily. Specifically, the problem of using an oxygen cylinder, a nitrogen cylinder, and a carbon dioxide cylinder in order to use microbubbles in the cell culture research field is solved.

  In addition, the use of carbon dioxide microbubbles in ordinary homes is the realization that it is desirable to purchase dry ice at home.

  As a premise of the present invention, there are cases where microbubbles by the technique of Patent Document 1 are used. The reason is that the particle size of the microbubbles produced by the technique of Patent Document 1 is relatively small and the production is stable, and its usefulness has been proved by utilizing various microbubbles. Bubble generation including at least microbubbles having a particle size of 30 μm or less can be realized.

  What is important here is the use of a vortex pump pump that draws gas at atmospheric pressure, although scientific explanation is currently under study. Here, when the vaporization method of “solidified gas (dry ice)” in Patent Document 4 and Patent Document 5 is seen, if the description of the generation of microbubbles by gas obtained by vaporization is seen, the atmospheric pressure or more is exceeded by vaporization. It can be seen that bubbling is performed at the gas pressure.

  Therefore, the technique of Patent Document 1 cannot be applied to the techniques of Patent Documents 4 and 5.

  Therefore, the inventor solved the above problem (the technique of Patent Document 1 cannot be applied to the techniques of Patent Documents 4 to 5) as follows.

  That is, (see FIG. 1, claims 1 and 4), the apparatus is a microbubble generator comprising a gas suction means, a liquid suction means, a liquid discharge means, and a main body means for generating a microgas connected to these. The microbubbles include at least microbubbles having a particle size of 30 μm or less. The gas suction means is further connected to a gas phase gas container (G), a solidified gas container connected to the G, or a liquefaction. A microbubble generator having a gas container (SL), which has, as a composition, a gas suction means, a liquid suction means, a liquid discharge means, and a main body means for generating a microgas to which these are connected. A microbubble-containing composition produced by using a vessel, the microbubble containing at least a microbubble having a particle size of 30 μm or less, further connected to the gas suction means The solid gas or liquefied gas is vaporized by the microbubble generator provided with the gas phase gas container (G), the solidified gas container or the liquefied gas container (SL) connected to the G. And a microbubble-containing composition formed by discharging the microbubbles from the liquid discharge means.

  (See FIG. 1, claims 2 and 5), means 3 for raising the temperature of the solidified gas container or liquefied gas container (SL) and vaporizing, and means for detecting the gas pressure in the gas phase gas container (G) And vaporization control means P1 for issuing a temperature raising command to the means 3 for raising the temperature of (SL) based on the detected pressure of the means for detecting the gas pressure and vaporizing the solidified gas or the liquefied gas. A microbubble generator comprising, as a composition, a means for raising the temperature of the solidified gas container or the liquefied gas container (SL) to vaporize, and a means for detecting the gas pressure of the gas phase gas container (G), And vaporization control means P1 for issuing a temperature raising command to the means 3 for raising the temperature of (SL) and evaporating the solidified gas or the liquefied gas based on the detected pressure of the means P for detecting the gas pressure. The gas in the gas phase gas container (G) The while maintaining the 慨 ne atmospheric pressure, which is the gas suction means solidified gas or liquefied gas vaporization becomes by suction compositions.

  Naturally (claims 3 and 7), the solidified gas or the liquefied gas is nitrogen (N2), oxygen (O2) or carbon dioxide (CO2).

  (Claim 6) In the apparatus, vaporization control means for raising the temperature of (SL) to issue a temperature raising command to the means for vaporizing the solidified gas or the liquefied gas, the gas pressure of the gas phase gas container (G) is increased. It is preferable for the control to be maintained at atmospheric pressure to be applied to the bubble generating device body of the vortex pump pump.

  In the present invention, the following effects can be obtained by a combination of these methods.

  According to the present invention, it is possible to use microbubbles more easily. For example, the problem of the research site that conventionally requires an oxygen cylinder, a nitrogen cylinder, and a carbon dioxide cylinder can be solved by using liquefied gas.

  In addition, when using carbon dioxide microbubbles at home, it is easy to purchase dry ice.

  As depicted in the upper left part of the solidified gas container or liquefied gas container 1 (SL), that is, the schematic diagram of the dry ice container in FIG. 1, the dry ice container can be freely opened and closed, and hermeticity is ensured when “closed”. It is a preferable aspect for practical use to have a canopy-shaped lid.

Schematic diagram of the microbubble generator of the present invention when the solidified gas is solidified carbon dioxide (CO2), that is, dry ice

1 Solidified gas container or liquefied gas container (SL)
2 Gas phase gas container (G), which has a pressure buffer tank (not shown). The pressure buffer tank is equipped with appropriate capacity adjusting means, and these maintain the vaporized gas pressure at approximately atmospheric pressure.
3 means for raising the temperature of (SL) to vaporize solidified gas or liquefied gas, and means for controlling the vaporization. For example, in the case of an electric heater, a Piaget element temperature control device, and dry ice, a water shower or water spray may be used.
4 Gas suction means 10 Microbubble generator 14 10 Liquid suction means (tip portion thereof)
15 10 Liquid discharge means (front end portion thereof)
P Means for detecting gas pressure in gas phase gas container (G)
Vaporization control means for issuing a temperature raising command to (3) based on the detected pressure of P1 P

Claims (7)

A microbubble-containing composition produced using a microbubble generator comprising a gas suction means, a liquid suction means, a liquid discharge means, and a main body means for generating a microgas to which these are connected,
The microbubbles include at least microbubbles having a particle size of 30 μm or less,
A gas phase gas container (G) further connected to the gas suction means;
By a microbubble generator having a solidified gas container or a liquefied gas container (SL) connected to the G,
Vaporize solidified gas or liquefied gas to form micro bubbles,
A microbubble-containing composition formed by discharging the microbubbles from the liquid discharge means. The composition of claim 1, wherein
Means for raising the temperature of the solidified gas container or the liquefied gas container (SL) to vaporize; and
Means for detecting the gas pressure of the gas phase gas container (G), and
A vaporization control means for raising the temperature of the (SL) based on a detection pressure of the means for detecting the gas pressure and issuing a temperature increase command to the means for vaporizing the solidified gas or the liquefied gas;
Further comprising
While holding the gas pressure of the gas phase gas container (G) at atmospheric pressure,
A composition obtained by evaporating and sucking a solidified gas or a liquefied gas in the gas suction means. In the composition of claim 1 or claim 2,
Solidified or liquefied gas
A composition which is nitrogen (N2) or oxygen (O2) or carbon dioxide (CO2). A microbubble generator comprising a gas suction means, a liquid suction means, a liquid discharge means, and a main body means for generating a microgas to which these are connected,
The microbubbles include at least microbubbles having a particle size of 30 μm or less,
A gas phase gas container (G) further connected to the gas suction means,
A microbubble generator comprising a solidified gas container or a liquefied gas container (SL) connected to the G. The microbubble generator of claim 4,
Means for raising the temperature of the solidified gas container or the liquefied gas container (SL) to vaporize; and
Means for detecting the gas pressure of the gas phase gas container (G), and
A vaporization control means for raising the temperature of the (SL) based on a detection pressure of the means for detecting the gas pressure and issuing a temperature increase command to the means for vaporizing the solidified gas or the liquefied gas;
A microbubble generator further comprising: The microbubble generator of claim 4,
A vaporization control means for issuing a temperature elevation command to the means for raising the temperature of (SL) to vaporize the solidified gas or the liquefied gas;
A microbubble generator that controls the gas pressure in the gas phase gas container (G) to maintain the atmospheric pressure. The microbubble generator according to any one of claims 4 to 6,
Solidified or liquefied gas
A microbubble generator that is nitrogen (N2) or oxygen (O2) or carbon dioxide (CO2).

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