JP3209382U - Bubble car - Google Patents

Abstract

The present invention provides a new bubble generator for a bubble generator, which is superior in operability, small size and low cost, for generating cleaning bubbles in an environment where hydrogen bubbles are generated. A foam generator that rotates rotating blades 1, 2, and 3 to generate washing bubbles of fine particles with hot water or detergent has a predetermined size in a reservoir 22 of the detergent provided at the bottom of hot water or a container body 17. A plurality of ceramic balls 21 are arranged, and in order to prevent the ceramic balls 21 from being damaged by touching the rotating blades 1, 2, 3, the storage portion 22 is formed deeper than the outer diameter of the ceramic balls 21, or the rotating blade 1 By placing a creper that also serves as a ball protector between 2, 3 and the ceramic ball 21, the rotating blades 1, 2, 3 are rotated manually or automatically while generating hydrogen bubbles to produce dense cleaning bubbles. Generate. [Selection] Figure 1

Description

The present invention makes it easy to include air in the cleaning foam generated by generating hydrogen bubbles when creating soap bubbles using soaps such as liquid soap and granular soap and detergents such as face wash. The present invention relates to a foam generator for a cleaning agent that generates clean cleaning foam.

When cleaning the skin with a cleaning agent, it is recommended to use cleaning foam generated from the cleaning agent in order to effectively remove dirt on the surface of the skin. Although the vessel has been put to practical use, it is desirable to generate hydrogen bubbles in the bubble generation environment in order to generate dense washing bubbles, so put ceramic balls for hydrogen generation in the net and rub them by hand A method of generating cleaning bubbles together with hydrogen bubbles is mainly used, but this method has various problems.

Problems that the device tries to solve

There is a difficulty in creating a fine particle cleaning foam by hand squeezing it using a net, so multiple ceramic balls are put in the net to produce a denser cleaning foam. Put it in with hot water or detergent, but it may be cumbersome and unusable for some people, and the ceramic balls may collide with each other and break down, causing debris to mix with the cleaning foam. Since it has problems such as easy generation, a new bubble generator with improved operability, small size, and low cost for generating cleaning bubbles in an environment where hydrogen bubbles are generated is provided.

Means for solving the problem

When the rotating blades are rotated to produce washing bubbles of fine particles with hot water or detergent, if hydrogen bubbles are present in the production environment, denser washing bubbles can be produced, thus constituting a reservoir for hot water and detergent. In addition, by placing a plurality of ceramic balls of a predetermined size in the reservoir, soaking the ceramic balls in hot water or detergent in the reservoir, and providing a ball protector structure that prevents the rotating blades from contacting the ceramic balls directly, hydrogen bubbles are generated. The cleaning blade is generated by rotating the rotary blade manually or automatically.

Effect of device

When a plurality of ceramic balls are immersed in water or a detergent in the reservoir, the ceramic balls are oxidized and reduced simultaneously due to a potential difference, and direct current electricity is generated and water is electrolyzed to generate hydrogen bubbles. In such an environment, the rotating blades are rotated to generate cleaning bubbles with hot water or a detergent, whereby dense cleaning bubbles with fine particles are generated. However, if the ceramic balls hit the rotating blades during foam generation, the ceramic balls will be damaged, causing problems such as debris mixing with the cleaning foam, so a ball protector that prevents the rotating blades from coming into direct contact with the ceramic balls should be provided. Thus, it is possible to generate dense foam bubbles by manually or automatically rotating the rotating blades while generating hydrogen bubbles.

The structure according to the present invention injects hot water or detergent that generates bubbles into the container body and collects it in the reservoir at the bottom of the container body, but the detergent is dissolved in hot water or the through hole at the tip of the rotary blade When the rotating blade rotates in this state, the tip of the rotating blade and the through hole at the tip are immersed in the hot water, and the rotation of the hot water passing through the hot water is repeated. This movement dissolves detergent, etc. in hot water, and when the through hole soaked in hot water comes out of the hot water, it generates soap bubbles in the form of soap bubbles. Small cleaning bubbles are generated by re-passing through the through holes of the rotating blades, but in order to generate a denser cleaning bubble, it is necessary to generate the cleaning bubbles in a hydrogen bubble environment. When a ceramic ball is immersed in hot water or detergent, oxidation and reduction start simultaneously due to a potential difference, direct current electricity is generated, water is electrolyzed, and hydrogen bubbles are generated.

FIG. 1 shows a conceptual diagram of a manual bubble wheel according to the present invention. A shaft 5 is formed on both sides of a support column 6 connected to the cap 8, and two rotary blades 1, 2, 3, 4 are formed on each side shaft, and these rotary blades rotate together with the shaft. The ferromagnetic material 7 is attached to at least one of the rotating blades to form a bubble generating unit. A cap, a support | pillar, a rotary blade, etc. are formed with a resin material, and a ferromagnetic material is formed with SUS430, iron, etc. A rotating plate 11 that rotates by rotating the rotary knob 18 by hand is formed on the outer surface of the container main body 17 that contains hot water, detergent, washing bubbles, and hydrogen bubbles. The rotating plate 11 has a ferromagnetic plate attached to the rotating blades. A magnet 12 is disposed at a position to be attracted by the body and magnetic force, and the rotating blade is attracted and rotated by the magnetic force by the rotation of the rotating plate. 22 constitutes a reservoir for hot water and detergent, and ceramic balls 21 are arranged in the reservoir, and the hot water and detergent in the reservoir containing the ceramic balls do not touch the rotating blades to prevent damage to the ceramic balls. Even if cleaning foam is generated at the position, it remains in the reservoir and generates hydrogen bubbles due to ceramic balls. In addition, regarding the storage part, there may be a structure that does not constitute a special groove structure, and a gap is provided between the scraper and the bottom of the container body so that the ceramic balls do not touch the scraper, and the storage part is hot water or detergent in the container body. May be part of the injection site.

FIG. 2 is a conceptual diagram of a foam generating unit formed by rotating blades 1, 2, 3, 4 and the like and not equipped with a creper. FIG. 3 shows a conceptual diagram of a foam generation unit provided with a creper 19 for taking out the generated foam. In FIG. 3, a water draining small hole 20 is formed, but when this foam generation unit is attached to a container body, Since the scraper 19 is located above the reservoir 22 for hot water, detergent, etc., it also serves as a ball protector, preventing the rotating blades from hitting the ceramic balls and preventing troubles such as breakage of the ceramic balls and mixing of debris with the cleaning foam. Can be removed. FIG. 4 shows a conceptual diagram of a manual bubble wheel in which a plurality of ceramic balls 21 having a predetermined size are arranged inside a ball protector 23 formed at the tip of the rotary blade 2. FIG. 5 is a conceptual diagram of the ball protector 23. When the rotating blade 2 reaches the bottom of the container body with the ball 21 attached, the bubble protector is immersed in hot water or detergent in the reservoir through the opening 24 of the ball protector 23 to generate hydrogen bubbles. It is a structure that generates

FIG. 6 is a conceptual diagram of the configuration of the electric bubble wheel. A rotating plate 11 that is rotated by a driving belt 14 via a driving plate 13 that transmits rotation of a motor 15 is formed on the outer surface of a container body 17 that stores hot water, detergent, and foam. A magnet 12 is disposed at a position attracted by a magnetic body and a ferromagnetic body attached to the rotating body, and the rotating blades are attracted and rotated by a magnetic force by the rotation of the rotating plate. The driving plate and the rotating plate are formed of a resin material, and the driving belt is formed of a rubber material. The magnet is composed of a strong magnetic neodymium magnet. The function of generating hydrogen bubbles is the same as that described with reference to FIG. 1, and the ceramic is made of a metal such as Ca (calcium), Mg (magnesium), K (potassium), Fe (iron), or Zn (zinc). When the ball touches water, oxidation and reduction start simultaneously due to the potential difference, and direct current electricity is generated, water is electrolyzed and hydrogen bubbles are generated.

The cap and the container main body were formed of transparent polycarbonate, the foam storage size of the container main body was 50 × 60 × 100 mm in width × thickness × height, and the internal volume was about 300 ml. The rotating blades were 23 × 28 mm, eight 1.5 mm thick, made of ABS resin, and the through holes were φ3.0 mm. The creper is a semicircular arc shape, 1.5 mm thick, and an ABS resin plate that fits the container body, and has a configuration in which a small hole of φ2 mm is formed and fitted into the support column. A ferromagnetic SUS430 was attached to the rotating blade, a neodymium magnet was placed on the rotating plate at a position adjacent to the rotating blade ferromagnetic material, and a small DC motor was used as the electric motor. In addition, five ceramic balls having a diameter of 3 mm and mainly made of Mg (magnesium) were used.

A magnet may be used for both the rotating blade and the rotating plate, a magnet may be used for the rotating blade, and a ferromagnetic material may be used for the rotating plate. The through holes are about φ2 to φ5 mm, and the number of rotating blades can be appropriately selected according to the number of through holes and the container body size. The magnet may be a samarium cobalt magnet or a ferrite magnet as long as the magnetic force is satisfied. The ceramic balls are made of metal such as Ca (calcium), Mg (magnesium), K (potassium), Fe (iron), Zn (zinc), etc., and the reaction rate and size with water can be optimized freely. is there. Further, the rotary knob is not limited to the knob, but may be a finger-holding structure. The rotation plate and the drive plate may be connected to each other not only by a belt but also by a gear. In addition, the rotating blades may be directly connected to the drive source without using a magnet, etc., such as displaying a marker line that guides the height of the hot water injected into the main body container, functions, performance, appearance, materials used, With respect to the dimension and the like, various modifications can be made without departing from the spirit of the present invention.

Fig. 2 shows a conceptual diagram of a manual bubble wheel according to the present invention. A conceptual diagram of a bubble generation unit formed with rotating blades is shown. A conceptual diagram of a foam generation unit equipped with a creper is shown. Fig. 2 shows a conceptual diagram of a manual bubble wheel according to the present invention. A conceptual diagram of a ball protector attached to a rotating blade is shown. The composition conceptual diagram of the electric bubble wheel based on this invention is shown

1. Rotating blade 11. Rotating plate Rotary blade 12. Magnet 3. Rotary blade 13. Drive plate 4. Rotary blade 14. 4. Driving belt Axis 15. Motor 6. Prop 16. Battery 7. Ferromagnetic material 17. Container body 21. Ceramic ball 8. Cap 18. Rotary knob 22. Reservoir 9. Cap picking 19. Creper 23. Ball protector10. Rotating blade rotation direction 20. Small hole 24. Aperture

Claims (2)

Concerning a foam generator that generates washing bubbles of fine particles with hot water and detergent by rotating a rotating blade, a reservoir for hot water and detergent is configured, and a plurality of ceramic balls of a predetermined size are arranged in the reservoir, and the ceramic ball A bubble wheel that generates a dense washing bubble by rotating a rotating blade manually or automatically while generating hydrogen bubbles by providing a ball protector that does not directly contact the rotating blade. Provided with a plurality of ceramic balls of a predetermined size at the tip of the rotary blade, with an opening for immersing the ceramic ball in hot water or detergent, and a ball protector for preventing the ceramic ball from directly contacting the container body The foam wheel according to claim 1.

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