KR20200000734U - Micro Nano Bubble Shower Head - Google Patents

Abstract

The present invention provides a micro-nano-bubble shower head, and in the micro-nano-bubble shower head sequentially comprising a main body of an intake section (1), a mixing section (2), and an exit means, at the right end of the intake section (1) It is characterized in that the air inlet hole 4 is installed, the air inlet hole 4 is installed in the back of the conical port reduction portion of the inlet section 1, and the micro-nanobubble generator is installed in the body.

Description

Micro Nano Bubble Shower Head

The present invention relates to a bubble shower head, and in particular to a micro nano bubble shower head used in the bathroom field.

Micro-nanobubbles have characteristics such as small bubble size, large specific surface area, high suction efficiency, slow rise rate and strong oxidizing property. When micro-nanobubbles are injected into water, solid foreign substances in water are effectively separated and water It has the advantage of rapidly increasing the oxygen concentration and dissipating harmful bacteria in the water. Compared to other treatment methods, micro-nanobubbles are also characterized by simple operation, low consumption, and no secondary contamination.

However, the shower head currently used only has a micro nanobubble generator with a transfer connection method, and also generates negative pressure with water flow only at the outlet of the product to mix the air with water, so that the air content is slightly higher. To manufacture. However, the mixing of gas and water is not sufficient. In addition, existing products do not generate micro-nano bubbles, and the generated bubbles also have no sterilizing effect.

The micro nanobubble shower head provided by the present invention has an advantage of sufficiently mixing water and gas and having a sterilizing effect.

In order to realize the above advantages, the present invention provides the following technical solutions.

In the micro-nanobubble shower head comprising a body in which the inlet section, the mixing section, and the outlet means are sequentially installed from left to right, an air inlet hole is provided at the right end of the inlet section, and the air inlet hole is a cone of the inlet section It is installed on the back of the port reduction portion, and the micro-nanobubble generator is installed in the main body.

As one improvement on the above technical method, the micro nanobubble generator includes a first micro nanobubble generator and a second micro nanobubble generator, and the first micro nanobubble generator is mounted inside the mixing section. A micro nanobubble is generated by including a first mixing device and a first shearing device, and the second micro nanobubble generating device comprises a second mixing device and a second shearing device installed below the outlet of the outlet means. To generate a bubble, the first shearing device includes at least one first shearing device metal mesh, the second shearing device comprises at least one second shearing device metal mesh, and the first mixing device comprises at least one manufacturing agent. 1, the mixing device includes a metal mesh, the second mixing device includes at least one second mixing device metal mesh, and the first micro nanobubble generating device comprises a first shear A second metal mesh group comprising a first metal mesh group comprising a dental metal mesh and a first mixing device metal mesh, and a second micro nanobubble generator comprising a second shear device metal mesh and a second mixing device metal mesh It includes.

As one improvement on the above technical solution, the micro nanobubble generator includes a first micro nanobubble generator, and the first micro nanobubble generator comprises a first mixing device and a first shear mounted inside the mixing section. Including a device to generate micro nanobubbles, the first shearing device comprises at least one first shearing device metal mesh, and the first mixing device comprises at least one first mixinger metal mesh, and the first micro The nanobubble generator comprises a first metal mesh group comprising a first shear metal mesh and a first mixed metal mesh.

As one improvement on the above technical solution, the micro-nanobubble generator includes a second micro-nanobubble generator, and the second micro-nanobubble generator comprises a second mixing device and a second installed under the outlet of the outlet. The second shearing device includes at least one second shearing device metal mesh, and the second mixing device comprises at least one second mixing device metal mesh by including a second shearing device. The 2 micro nanobubble generator includes a second metal mesh group comprising a second shear metal mesh and a second mixing metal mesh.

As one improvement to the above technical method, the micropore of the first shearing device metal mesh is 1000 mesh or more.

As one improvement on the above technical method, the pore size of the second shearing device metal mesh is 1000 mesh or more.

As a further improvement to the above technical solution, the pore size of the first mixing device metal mesh is 1000 mesh or less.

As one improvement on the above technical solution, the pore size of the second mixing device metal mesh is 1000 mesh or less.

As an improvement to the above technique, the intake section includes a reduced conical port to allow water to enter the mixing section through the occipital part of the intake hole.

As one improvement on the above technical method, a plurality of air inlets arranged along the inside of the outer circumferential surface of the main body is further installed, a check valve is installed in the inlet section, and a filter metal mesh is disposed at the front end of the check valve. By being installed, it filters out foreign substances in water and generates an initial turbulence in the water, and the air intake device transports air to the mixing section by including a conical port installed at the left end of the mixing section.

Compared to the prior art, the present invention has an advantage of sufficiently mixing water and gas and having a sterilizing effect. And additionally 1) Since the air inlet end is at the end of the product, the product looks good, and there is no fear of shielding the air inlet when carried by hand; 2) Cleans the deep pores of the skin and keeps the skin's oxygen content higher and longer than normal water; 3) It has the advantage of low manufacturing cost.

Other advantages and features are fully understood from the detailed description of the embodiments with reference to the drawings below, and the accompanying drawings must be considered in an explanatory and non-limiting way. among them,
1 is a schematic configuration diagram of a micro nano bubble shower head according to the present invention.
FIG. 2 is a left side view of FIG. 1.
FIG. 3 is a plan view of FIG. 1;
4 is a schematic configuration diagram of a micro nanobubble shower head according to another invention.
5 is a schematic configuration diagram of a micro nanobubble shower head according to another invention.

The technical plan of the present invention will be clearly and completely described in conjunction with the accompanying drawings below. Of course, the embodiments to be described below are only some of the embodiments of the present invention, and not all of them. According to the embodiments of the present invention, all other embodiments obtained without creative efforts by those skilled in the art to which the invention pertains fall within the protection scope of the present invention.

In describing the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "my", "other", etc. The direction or positional relationship indicated is a direction or positional relationship according to the accompanying drawings, which are merely for conveniently explaining the present invention and for simplifying the description, and that a corresponding device or device must be configured and operated in a specific direction with a specific direction. It is not to be pointed or implied and should not be understood as a limitation on the present design. Meanwhile, the terms "first", "second", and "third" are used for the purpose of explanation only and should not be understood as indicating or implying relative importance.

In describing the present invention, it should be noted that the terms "mounted", "connected to each other" and "connected" should be understood in a broad sense, unless otherwise specified. For example, it may be a fixed connection, it may be a detachable connection or an integral connection; It can be a mechanical connection, it can be an electrical connection, it can be connected directly or through an intermediate medium. Also, the two elements may be in communication. Those of ordinary skill in the art to which the invention pertains can understand the specific meaning of the term in the present invention according to the specific situation.

On the other hand, the technical features mentioned in other embodiments of the present invention to be described below can be combined if they do not collide with each other.

1 to 3, where FIG. 2 is a left configuration diagram of FIG. 1 and FIG. 3 is a plan configuration diagram of FIG. 1. The micro-nanobubble shower head provided in the present invention has a micro-nanobubble generating device packaged therein, and the main body is sequentially installed from left to right with the inlet section (1), mixing section (2), and outlet (3). And the air inlet hole 4 is installed at the right end of the inlet section 1. The range of the inlet section 1 ranges from the leftmost filter metal mesh 8 to the front end of the occipital head of the conical reduction hole at the front end of the air inlet hole 4. The range of the mixing section 2 ranges from the occipital channel of the air inlet hole 4 to the channel between the rearmost front end 6 of the head. Here, the air inlet device from the air inlet 9 located at the bottom of the shower head to the air inlet hole 4 and the product structure 11 having an external appearance are further included. The water in the shower hose is guided to the micro nanobubble generator and flows through the filter metal mesh (8), then flows through the conical reduction hole at the inlet end into the waterway occipital region, thereby generating negative pressure, thereby causing the air inlet hole (4) ) To inhale air into the waterway. Then, after passing through the inner chamber of the waterway and the first mixing device 7, the second mixing device 10 and the first shearing device 5, and the second shearing device 6, the micrometer is passed through the exit means 3 again. Generates the number of nanobubbles.

The inlet section 1 is used to draw water from the hose into the micro nanobubble shower head, the mixing section 2 is an area for mixing air and water into one, and the outlet means 3 is sufficiently mixed with air and water The mixture is used to drain the micro nanobubble shower head out.

1, in an embodiment of the present invention, the micro nanobubble generator includes a first micro nanobubble generator and a second micro nanobubble generator, and the first micro nanobubble generator comprises a mixing section. (2) By including the first mixing device 7 and the first shearing device 5 mounted therein to generate micro nanobubbles, the second micro nanobubble generating device is located below the outlet of the outlet means 3 Micro nanobubbles are generated by including the installed second mixing device 10 and the second shearing device 6, and the first shearing device 5 includes at least one first shearing device metal mesh, and second shearing The device 6 comprises at least one second shearing device metal mesh, the first mixing device 7 comprises at least one first mixing device metal mesh, and the second mixing device 10 comprises at least one metal mesh. A second mixing device including a metal mesh, the first micro The nanobubble generator comprises a first metal mesh group comprising a first shear device metal mesh and a first mixing device metal mesh, and the second micro nanobubble generator is a second shear device metal mesh and a second mixing device metal mesh. It is preferable to include a second metal mesh group comprising a.

In another embodiment of the present invention, a separator is installed between each layer of the first shearing device metal mesh and the first mixing device metal mesh to generate a rapid turbulence in water to sufficiently dissolve the gas in water and the first shearing device metal. It is preferable to generate micro nanobubbles using a network.

In another embodiment of the present invention, a separator is installed between each layer of the second shearing device metal mesh and the second mixing device metal mesh to generate a rapid turbulence in water to sufficiently dissolve the gas in water and the second shearing device metal. It is preferable to generate micro nanobubbles using a network.

4, in another embodiment of the present invention, the micro nanobubble generator comprises a first micro nanobubble generator, and the first micro nanobubble generator comprises a mixing section 2 Micro nanobubbles are generated by including the mounted first mixing device 7 and the first shearing device 5, and the first shearing device 5 includes at least one first shearing device metal mesh, and the first The mixing device 7 includes at least one first mixing device metal mesh, and the first micro nanobubble generating device includes a first metal mesh group including a first shearing device metal mesh and a first mixing device metal mesh. It is desirable to do.

In another embodiment of the present invention, a separator is installed between each layer of the first shearing device metal mesh and the first mixing device metal mesh to generate a rapid turbulence in water to sufficiently dissolve the gas in water and the first shearing device metal. It is preferable to generate micro nanobubbles using a network.

As shown in Figure 5, in another embodiment of the present invention, the micro-nanobubble generator comprises a second micro-nanobubble generator, and the second micro-nanobubble generator, the outlet of the exit means (3) Micro nanobubbles are generated by including the second mixing device 10 and the second shearing device 6 installed at the bottom of the unit, and the second shearing device 6 includes at least one metal network of the second shearing device, The second mixing device 10 includes at least one second mixing device metal mesh, and the second micro nanobubble generating device includes a second metal mesh group including a second shearing device metal mesh and a second mixing device metal mesh. It is preferable to include a.

In another embodiment of the present invention, a separator is installed between each layer of the second shearing device metal mesh and the second mixing device metal mesh to generate a rapid turbulence in water to sufficiently dissolve the gas in water and the second shearing device metal. It is preferable to generate micro nanobubbles using a network.

In an embodiment of the present invention, in order to prevent reflow, a check valve is installed in the intake section 1, and a filter metal mesh 8 is installed at the front end of the check valve to filter foreign substances in water and generate turbulence in water. Order. The filter metal net 8 is located at the very front end of the micro-nanobubble generator and water is preferably introduced into the mixing section 2 through a conical port of the water channel.

In the embodiment of the present invention, it is preferable that the air inflow device transfers air to the mixing section 2 by including a conical port installed at the left end of the mixing section 2. The air inflow device passes through the air inlet 9 at the bottom of the shower head and passes through the occipital part of the water channel to install the air inlet hole 9 (see FIG. 2) to introduce air into the water channel. As shown in the figure, the water channel undergoes initial gas-liquid mixing through the chamber of the expansion section behind the occipital head. In another embodiment, the shape of the conical port can be made into any shape as long as it plays the same role.

In the embodiment of the present invention, it is preferable that a plurality of air inflow holes 4 are uniformly disposed along the circumference of the main body. In another embodiment, the air inlet hole can be installed to be arranged non-uniformly along the circumference 11 of the body.

In the embodiment of the present invention, it is preferable that the shearing device 6 is installed below the exit means 3 and the mixing device 10 is installed below the shearing device 6. This can compensate or control the adjustment to increase or decrease the corresponding device due to the hydraulic environment, so that the gas and water are mixed more sufficiently to generate micro nanobubbles through the shearing device 6.

In the embodiment of the present invention, the pores of the first shearing device metal mesh are preferably 1000 mesh or more so as to more smoothly shear and filter the liquid after gas-liquid mixing.

In the embodiment of the present invention, the pores of the second shearing device metal mesh are preferably 1000 mesh or more so as to more smoothly shear and filter the liquid after gas-liquid mixing.

In the embodiment of the present invention, it is preferable that the pores of the first mixing device metal mesh are 1000 mesh or less.

In the embodiment of the present invention, the pores of the second mixing device metal mesh are preferably 1000 mesh or less.

In an embodiment of the present invention, it is preferred to have a conical port in the inlet section so that water is introduced into the mixing section 2 from the occipital portion of the intake hole 4.

In the embodiment of the present invention, a plurality of air inlets 9 arranged along the inside of the circumferential outer surface 11 of the main body are further installed, a check valve is installed in the intake section 1, and A filter metal mesh 8 is installed at the front end to filter foreign substances in water and generate initial turbulence in the water. The air inlet device transfers air to the mixing section 2 by including an air inlet hole 4 installed in the occipital region located at the left end of the mixing section 2.

The following is a table of the number of fine meshes and meshes on the market, showing the number of fines and meshes in contrast.

Mesh number Pore (μm) Mesh number Pore (μm) Mesh number Pore (μm) 100 150 175 86 400 38 115 125 180 80 500 25 120 120 200 75 600 23 125 115 230 62 800 18 130 113 240 61 1000 13 140 109 250 58 1340 10 150 106 270 53 2000 6.5 160 96 300 48 5000 2.6 170 90 325 45

What should be described here, each data shown in the above table is data corresponding to only some of the various combinations used by the inventor, and the present invention is not limited to this, and other combinations will not be listed one by one here. Referring to the above table, it can be seen that the micro nanobubble effect generated is not the same because the size of the pores corresponding to the metal mesh is different for each mesh number.

At the same time, when water passes through the metal mesh, bubbles can be instantaneously ruptured due to the pressure difference, thereby killing bacteria. Therefore, the micro nanobubble shower head of the present invention further has a sterilizing function.

Compared to the prior art, the present invention has an advantage of sufficiently mixing water and gas and having a sterilizing effect. And additionally 1) Since the air inlet end is at the end of the product, the product looks good, and there is no fear of shielding the air inlet when carried by hand; 2) Cleans the deep pores of the skin and keeps the skin's oxygen content higher and longer than normal water; 3) It has the advantage of low manufacturing cost.

Of course, the above embodiment is only an example for clearly explaining the present invention, and the embodiment is not limited thereto. For those of ordinary skill in the art to which the invention pertains, changes or modifications may be made in other forms by the above description. It is not necessary to mention all the embodiments here, nor can all of them be mentioned. Significant changes or changes extended therefrom still fall within the protection scope of the invention.

Claims (10)

In the micro-nanobubble shower head comprising a body in which the intake section 1, the mixing section 2, and the outlet means are sequentially installed from left to right,
The air inlet hole 4 is installed at the right end of the inlet section 1, and the air inlet hole 4 is installed at the back of the conical port reduction portion of the inlet section 1, and the micro nanobubble generating device is the main body. Micro nanobubble shower head, characterized in that installed inside. The method according to claim 1,
The micro nanobubble generator includes a first micro nanobubble generator and a second micro nanobubble generator, and the first micro nanobubble generator is a first mixing device 7 mounted inside the mixing section 2 And a first shearing device 5 to generate micro nanobubbles, and the second micro nanobubble generating device includes a second mixing device 10 and a second shearing device installed below the outlet of the outlet means 3. (6) to generate micro nanobubbles, the first shearing device (5) includes at least one first shearing device metal mesh, and the second shearing device (6) comprises at least one second shearing device metal Includes a mesh, the first mixing device 7 comprises at least one first mixing device metal mesh, the second mixing device 10 includes at least one second mixing device metal mesh, and the first micro The nanobubble generating device is the first shearing device metal mesh and 1 comprising a first metal mesh group comprising a mixing device metal mesh and a second micro nanobubble generator comprising a second metal mesh group comprising a second shear device metal mesh and a second mixing device metal mesh Micro nano bubble shower head. The method according to claim 1,
The micro nanobubble generator comprises a first micro nanobubble generator, and the first micro nanobubble generator comprises a first mixing device 7 and a first shear device 5 mounted inside the mixing section 2. By generating a micro nanobubble, the first shearing device 5 comprises at least one first shearing device metal mesh, and the first mixing device 7 comprises at least one first mixing device metal mesh. And, the first micro-nanobubble generating device is a micro-nanobubble shower head, characterized in that it comprises a first metal group including a first shear device metal mesh and the first mixing device metal mesh. The method according to claim 1,
The micro-nanobubble generator includes a second micro-nanobubble generator, and the second micro-nanobubble generator comprises a second mixing device 10 and a second shear device installed below the outlet of the outlet means 3 ( 6) to generate micro nanobubbles, the second shearing device 6 includes at least one second shearing device metal mesh, and the second mixing device 10 comprises at least one second mixing device metal mesh. Including, the second micro-nanobubble generating device is a micro-nanobubble shower head, characterized in that it comprises a second metal mesh group including a second shear device metal mesh and a second mixing device metal mesh. The method according to claim 2 or claim 3,
Micro nanobubble shower head, characterized in that the micropores of the first shearing device metal mesh are 1000 mesh or more. The method according to claim 2 or claim 4,
Micro nanobubble shower head, characterized in that the pores of the second shearing device metal mesh are 1000 mesh or more. The method according to claim 2 or claim 3,
Micro nanobubble shower head, characterized in that the first pore of the metal mesh of the first mixing device is 1000 mesh or less. The method according to claim 2 or claim 4,
Micro nanobubble shower head, characterized in that the micropore of the second mixing device metal mesh is 1000 mesh or less. The method according to claim 1,
The inlet section includes a reduced conical port to allow water to enter the mixing section (2) through the occipital head with an intake hole (4). The method according to claim 1,
A plurality of air inlets 9 arranged along the inside of the circumferential outer surface 11 of the main body are further installed, a check valve is installed in the intake section 1, to filter foreign substances in the water and to generate initial turbulence. A filter metal mesh 8 is installed at the front end of the check valve, and the air inlet device includes air to the mixing section 2 by including an air inlet hole 4 installed at the left end of the mixing section 2 Micro nanobubble shower head, characterized in that for conveying.

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