JP4868179B2 - Water heater - Google Patents

Description

  The present invention relates to an active water device that activates water using far infrared rays.

Conventionally, an active water device that obtains reducing water by bringing far-infrared rays into contact with water has been used. These active water devices use semi-permanently generated far-infrared rays, so that the properties of water are improved, so there is no need for replacement of the filter and the burden on the user is small. (For example, Patent Document 1)
However, many conventional active water devices using far-infrared rays have a far-infrared generating material that is nearly spherical, and the contact area with water is very small.

The problem is caused by the fact that the far-infrared ray generating material is often a ceramic, and it is difficult to form the far-infrared ray generating material into a shape that can change the water flow direction.
JP 2005-288385 A

  Accordingly, the present invention provides an active water device capable of increasing the contact area between a far-infrared ray generating substance and water in a pipe having a certain diameter and length, and sufficiently imparting the active water action of the far infrared light to water. The issue is to provide.

In order to solve the above problems, the present invention takes the following technical means.
(Invention of Claim 1)
This active water device has an inflow port, an outflow port, and a functionally gradient material, and the functionally gradient material generates far infrared rays by changing the central portion from the surface portion to aluminum from beta alumina. Inclined to generate far-infrared rays, characterized by being formed in a screw shape and provided in the active water device, and the water flow entering from the inflow port changes direction by the functionally gradient material and exits from the outflow port. By changing the direction of water flow using the functional material, the contact area between the far-infrared ray generating substance (gradient functional material) and water increases, and the effect that water receives from far-infrared rays increases.
And by using a functionally gradient material, it became possible to change the direction of water flow with the material itself that generates far infrared rays. The mode of changing the direction of the water flow may be rectification or turbulence, but a screw shape is preferred.
The functionally gradient material whose center portion from the surface portion is beta alumina to aluminum is preferable for forming a shape capable of changing the water flow direction.

(Invention of Claim 2)
This active water device relates to the invention according to claim 1, characterized in that the functionally oblique material is such that the beta alumina blending ratio decreases and the aluminum blending ratio increases as it moves from the surface to the center. To do.
Among the functionally gradient materials that are changed from beta alumina to aluminum, it is most preferable to use “Farox (registered trademark)” manufactured by Terumo Industries Co., Ltd., which has a very large amount of far infrared radiation.

(Invention of Claim 3)
This active water apparatus relates to the invention described in claim 2 , wherein the functionally oblique material has an emissivity of 70% to 91% of a black body in an infrared wavelength region of 4.0 μm to 10 μm .
“Pharmox (registered trademark) manufactured by Terumo Corporation” has at least the above emissivity.

(Invention of Claim 4)
This active water apparatus relates to the invention described in claim 3, wherein the screw shape is formed by three blades of the functionally gradient material.
When the functionally gradient material has a three-blade screw shape, the water flow is changed from a straight water flow to a swirling water flow. When the direction of the water flow is changed to the swirling water flow, the balance between the speed of the water flow and the contact area is good, and it becomes possible to efficiently absorb the far infrared rays in the water.

(Invention of Claim 5)
This active water device relates to the invention described in claim 4, and is characterized in that a plurality of functionally gradient materials formed into a three-blade screw shape are provided in a flowing water pipe having an inner diameter of 40 mm at intervals of 9 mm.
If a plurality of functionally gradient materials formed into a screw shape are provided at intervals of 9 mm in a flowing water pipe having an inner diameter of 40 mm, the speed of the swirling water flow and the contact area can be most preferably achieved.

  The active water device of the present invention increases the contact area between the far-infrared ray generating substance and water in a pipe having a constant diameter and length, and can sufficiently give the active water action of far infrared light to water. Is to provide.

  Below, the active water apparatus of this invention is demonstrated with each figure shown as an Example.

  FIG. 1 is an overall view of an active water apparatus according to a first embodiment. FIG. 2 is a partial cross-sectional view of the live water system according to the first embodiment. FIG. 3 is a graph of the radiation intensity of the functionally gradient material. FIG. 4 is a graph showing the emissivity of the radiation intensity of the functionally gradient material. FIG. 5 is a perspective view of a functionally gradient material formed into a three-blade screw shape.

[1-1: Basic configuration of the water activation apparatus 1]
This active water device 1 has an inlet 10 and an outlet 11, and is a device that is attached to a water pipe so that the water station side becomes the inlet 10 and the user side becomes the outlet 11. Attachment is not limited to tap water, but can also be used for well water, other industrial water, and the like. The attachment method is preferably screwed.
When the active water device 1 is attached, the water that has entered from the inflow port 10 is affected by the far-infrared rays while leaving the outflow port 11 and is activated to obtain reducible water. The ability to obtain reducing properties is not limited to water, and the same applies to liquor and other liquids.

[1-2: Detailed configuration of the water activation device 1]
As shown in FIG. 1, an inlet lid 20 and an outlet lid 30 are threadedly engaged with both ends of the flowing water pipe 2 in the longitudinal direction of the outside of the live water device 1. The inlet lid 20 is provided with the inlet 10, and the outlet lid 21 is provided with the outlet 11.
In the flowing water pipe 2, a functionally gradient material 3 that generates far infrared rays, a fixed shaft 4 that fixes the functionally gradient material 3, and a stopper 5 that fixes the fixed shaft 4 are provided.
The functionally gradient material 3 is fixed in such a manner as to be immovable by a fixed shaft 4, the fixed shaft 5 is fixed in a manner that penetrates the stopper 5, and the stopper 5 (shown) on the inlet 10 side is connected to the flowing water pipe 2. The stopper 5 (not shown) on the outlet 11 side is fixed by screwing the inlet water pipe 20 and the outlet lid 21.

[2-1: Functionally graded material 3]
As shown in FIG. 2, the functionally gradient material 3 is formed in a mode in which the direction of the water flow entering from the inlet 10 is changed. Conventional materials that generate far-infrared rays are often ceramic and difficult to mold. Therefore, by forming the functionally gradient material 3 in which the center portion from the surface portion is changed from beta alumina to aluminum, molding is possible.
With such a functionally gradient material 3, after forming aluminum, a far-infrared ray generating material having an arbitrary shape can be obtained by processing the surface to be beta alumina (ceramic).
The functionally gradient material 3 whose center portion from the surface portion is made of beta alumina to aluminum is preferably Farox (registered trademark) manufactured by Terumo Corporation.

[2-2: Structure of Farox (registered trademark) manufactured by Terumo Corporation]
Farox (registered trademark) used for the functionally gradient material 3 has a surface portion made of beta alumina and a center portion made of aluminum. As it moves from the surface to the center, the beta alumina blending ratio decreases and the aluminum blending ratio increases.
That is, Farox (registered trademark) is a functionally graded material 3 made in such a manner that the beta alumina in the surface portion is rooted in the inner aluminum.

[2-3: Characteristics of Farox (registered trademark) manufactured by Terumo Corporation]
This Farox (registered trademark) is a functionally gradient material 3 having the following characteristics.

(Infrared measurement)
A black body (an object that absorbs 100% of incident light and has the maximum energy radiation ability) was used as a reference material for comparing infrared radiation performance, and a test for examining the characteristics of Farox (registered trademark) was performed.
As a test method, both a black body and Farox (registered trademark) were measured with a Fourier transform infrared spectrophotometer (FTIR), and an infrared radiation intensity and an infrared radiation rate of a wavelength of 4.0 μm to 1000 μm were obtained.

(Infrared radiation intensity)
The measurement result of infrared radiation intensity is shown in FIG.
Since the aforementioned black body is an object having the maximum energy radiation ability, there is no infrared ray generating substance having a radiation intensity greater than that of the black body.
Farox (registered trademark) has a radiation characteristic close to that of a black body.

(About infrared emissivity)
The measurement result of infrared emissivity is shown in FIG.
The radiation intensity of the above-mentioned black body was set to 100%, and the emissivity of Farox (registered trademark) was measured.
Farox (registered trademark)
In the wavelength range of 4.0 μm to 10 μm, the emissivity is 70% to 91% of the black body,
The emissivity is 80% to 91% of the black body in the wavelength range of 6.0 μm to 10 μm.
It was the measurement result.

[2-4: About infrared rays]
Infrared is generally
・ Wavelength (WAVELENGTH in FIGS. 3 and 4) is 0.75 to 4.0 μm (in FIG. 3 and FIG. 4, “MICRON”). ) Is classified into two types of far infrared rays of 4.0 to 1000 μm (“MICRON” in FIGS. 3 and 4).

In the far-infrared wavelength range described above, the wavelength around 6.27 μm effectively vibrates water molecules by absorbing electromagnetic waves. By this vibration, water molecules are subdivided and water can be activated. From this, the gradient function has an emissivity of 70% to 91% of the black body in the wavelength range of 4.0 μm to 10 μm and an emissivity of 80% to 91% of the black body in the wavelength range of 6.0 μm to 10 μm. Material 3 (Farox (registered trademark)) is a material having a very large active water action.
For this reason, as the functionally gradient material 3, it is very preferable to use Farox (registered trademark) manufactured by Terumo Corporation.

[3-1: Shape of functionally gradient material 3]
The functionally gradient material 3 is formed into a three-blade screw shape having three blades 30 as shown in FIG. The shaft hole 31 at the center of the three blades is formed in a regular hexagon.
When the functionally gradient material 3 has a three-blade screw shape, the water flow is changed from a straight water flow to a swirling water flow. When the direction of the water flow is changed to the swirling water flow, the balance between the speed of the water flow and the contact area is good, and it becomes possible to efficiently absorb the far infrared rays in the water.
Further, since the shaft hole 31 is a regular hexagon, one blade 30 can be formed on the outer periphery and two sides of the hexagon, and the accuracy can be easily obtained.

When the inner diameter of the water pipe is 40 mm, it is preferable that a plurality of functionally gradient materials 3 formed in a three-blade screw shape are provided at intervals of 9 mm.
When a plurality of functionally gradient materials 3 formed in a screw shape are provided at intervals of 9 mm in a flowing water pipe having an inner diameter of 40 mm, the speed of the swirling water flow and the contact area can be achieved most preferably.
In the active water apparatus 1 of Example 1, the total length of the water flow pipe 2 was 230 mm, and 23 functionally gradient materials 3 were installed.

[3-2: Increase in contact area between water and functionally gradient material 2]
In order to sufficiently influence the far infrared rays on the water, it is preferable to increase the contact area between the far infrared rays and the water.
In the active water device of JP-A-2005-288385,
(Contact area of water) = 4 (diameter) × π × 23 (full length) = 92πcm ³
However, in the present embodiment,
(Water contact area) = 4 (radius square) × 2 (front / back) × π × 23 (full length) = 184πcm ³
2 times the contact area can be obtained.
Further, when the functionally gradient material 3 is provided on the inner wall of the water flow pipe together with the screw,
(Contact area of water) = 92π + 184π = 276πcm ³
Thus, a contact area three times as large can be obtained.

[4-1: Synergistic effect of material and structure]
Thus, the active water apparatus 1 synergizes the functionally gradient material 3 with high far-infrared radiation performance and the increase in contact area, and has the following effects.

[4-2: Verification experiment of effect of active water apparatus 1]
In order to verify the performance of the water activation apparatus 1, the following experiment was conducted.
FIG. 6 shows test results of tap water. FIG. 7 shows the test results after using the active water device.

(About used tap water)
The tap water used as a sample was tap water discharged from the tap of the inventor's address “4-1, 5-5, Oken, Kashihara, Osaka”.

(About use of the active water device 1)
In the active water device 1 for experiment, the total length of the flowing water pipe 2 was 230 mm, 23 functionally gradient materials 3 were installed at a pitch of 9 mm, and the functionally gradient material 3 was made of Farox (registered trademark). A sample in which 1000 cc of water was allowed to flow through the active water device 1 was used as a sample of water after passing through the active water device 1.

(Test method)
A sample of tap water was tested on the water after passing through the active water device 1 on May 14, 2008 at the Fujiidera Health Center in Osaka Prefecture, and test results (FIGS. 6 and 7) were obtained.

(Test results)
Based on FIG. 6 and FIG. 7, items in which changes were observed were summarized below, and Table 1 was obtained.

When tap water passes through the live water device 1,
A person skilled in the art can expect that general bacteria have been degraded from 29 (cfu / mL) to 0 (cfu / mL) and killed chloride ions from 17.2 (mg / L) to 16.8 (mg / L). No results were obtained.

  It is also known that when tap water (acidic) less than ph7 passes through an active water device that generates far-infrared rays, it is neutralized near ph7. Since the active water device 1 has not only high far-infrared radiation performance but also a large contact area, the above-described effects are naturally great.

It is a general view of the active water apparatus of Example 1. It is a fragmentary sectional view of the active water apparatus of Example 1. It is a graph of the radiation intensity of a functionally gradient material. It is a graph which shows the emissivity of the radiation intensity of a functionally gradient material. It is a perspective view of a functionally gradient material formed into a three-blade screw shape. It is a test result of tap water. It is a test result after using a water activation device.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Active water apparatus 10 Inlet 11 Outlet 2 Inflow pipe 3 Functionally gradient material

Claims (5)

The active water device has an inflow port, an outflow port, and a functionally gradient material.
The functionally gradient material generates far infrared rays by changing the central portion from the surface portion to aluminum from beta alumina, and is formed in a screw shape and provided in the active water device.
The water stream entering from the inlet changes direction by the functionally gradient material and exits from the outlet.
An active water device characterized by that. As the functionally gradient material moves from the surface portion to the central portion,
Beta alumina blend ratio decreases, aluminum blend ratio increases,
The water activation apparatus according to claim 1, wherein the water activation apparatus is a thing . The functionally gradient material is in the infrared wavelength region of 4.0 μm to 10 μm.
The active water apparatus according to claim 2 , wherein the emissivity is 70% to 91% of a black body . The live water device according to claim 3, wherein the screw shape is formed by three blades of the functionally gradient material. A functionally gradient material formed into a three-blade screw shape in a flowing water pipe having an inner diameter of 40 mm,
The active water apparatus according to claim 4, wherein a plurality of sheets are provided at intervals of 9 mm.