JP2005329046A - Rock heating bath facility - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide rock heating bath facility where heat conduction efficiency is improved by constituting an upper layer of a rock bath of a microporous water permeable concrete layer, which realizes a mist sauna effect by steam obtained by making the permeable concrete layer absorb water, and which utilizes radiation energy from the stone by using hornfels to the rock on a surface. <P>SOLUTION: Warm water pipes 1 are arranged under the water permeable concrete 3 layer, which is formed by mixing power of decomposed granite soil, soil modifier and hornfels to cement and hardening them. In addition, on the upper surface of the water permeable concrete 3 layer, the rock 4 consisting of hornfels is arranged. On the surface of the water permeable concrete 3, ceramic pieces 5 or rounded stones 6 are arranged. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a bedrock hot bath facility using hornfels.

In general, bathing facilities include a bathtub with hot water, a sauna with hot air, and the like, but there are bathing facilities with so-called bedrock baths that lie on a warm bedrock and obtain a thermal effect.
This bathing facility using a bedrock bath is to lay a towel, etc. on a bedrock warmed to 40 to 42 degrees and lie down in a bathing suit to obtain a thermal effect.
This bedrock bath has the effect of increasing the metabolism of blood by warming the body from the core by far-infrared rays just by lying down on the bedrock.
A technique described in Japanese Patent Application Laid-Open No. 2004-130047 is known as a technique related to such a bedrock hot bath facility.
JP 2004-130047 A

However, since the conventional rock bath has a hot water pipe as a heat source disposed under the concrete layer, the heat from the hot water pipe is not easily transmitted through the concrete layer, and the heat is not efficiently used. was there.
In addition, since a concrete layer is interposed between the heat source and the rock surface, it takes time to warm the rock surface, and it is difficult to adjust the temperature of the rock surface.
The present invention has been made in order to solve such conventional problems, and the object of the present invention is to improve the heat conduction efficiency by making the upper layer of the bedrock bath into a water-permeable concrete layer having fine pores, By providing water to the porous concrete layer, the mist sauna effect due to the steam is realized, and further, the bedrock thermal bath facility that uses the hornfels for the surface rock and uses the radiant energy from the stone is provided. is there.

  As means for achieving the above object, in the bedrock hot water bath facility according to claim 1 of the present invention, a hot portion is arranged under the permeable concrete layer.

  In the rock hot water bath facility according to claim 2, in the rock hot water bath facility according to claim 1, the permeable concrete layer is formed by mixing pure sand soil and soil improver into cement and solidifying them. .

  In the rock hot water bath facility according to claim 3, in the rock hot water bath facility according to claim 1 or 2, hornfels powder is mixed in addition to the cement, pure sand soil, and soil conditioner, and they are solidified to be permeable. A concrete layer is formed, and furthermore, a bedrock made of hornfels is arranged on the upper surface of the permeable concrete layer.

  The bedrock hot water bath facility according to claim 4, wherein a ceramic piece or a cobblestone is embedded in the surface of the water permeable concrete layer and the bather lies on his / her back at least. The bedrock is located on the shoulder, waist and legs.

  The bedrock hot-bath facility according to claim 5 is configured to obtain a mist sauna effect by impregnating water into a water-permeable concrete layer in the rock-bed hot bath facility according to any one of claims 1 to 4 and vapor of the water. .

In the bedrock hot-water bath facility of the present invention, since the hot portion is embedded in the permeable concrete layer, heat is efficiently conducted to the upper layer through the fine holes of the permeable concrete.
Moreover, by allowing water to permeate through the fine pores of the water-permeable concrete, the thermal conductivity is further improved through the water, and the absorbed water is diffused as steam, thereby obtaining a mist sauna effect.
And since a water-permeable concrete is formed using a soil improvement agent by making a pure sand soil into a main material, a micropore is formed reliably.
Furthermore, since hornfels powder is mixed in the permeable concrete layer and hornfels rock is used for the surface layer, a healing effect is obtained by the energy radiated from the hornfels.
Moreover, since ceramic pieces or cobblestones are embedded in the surface of the water-permeable concrete layer, in addition to hornfels, a healing effect by far infrared rays, negative ions, etc. from these stone pieces can be obtained.
In addition, since the bedrock is placed at least on the back, waist, and ankles, the bather tends to lie down, and energy from hornfels is reliably irradiated to the main part of the body.

  The best mode for realizing the bedrock hot water bath facility of the present invention will be described below with reference to the drawings.

As shown in FIGS. 1 to 3, the bedrock hot water bath facility of the present invention includes a hot water pipe 1 (heated part) arranged under the floor, a heat storage concrete layer 2 in which the hot water pipe 1 is embedded, and the heat storage concrete layer 2. The main components are the water-permeable concrete 3 arranged in the upper layer, the rock mass 4 arranged on the surface of the water-permeable concrete 3, and the ceramic pieces 5 and the cobblestones 6 scattered between the rock mass 4.
The heat storage concrete layer 2 receives heat from the hot water pipe 1 and the entire layer becomes a heat source, and conducts heat to the upper permeable concrete 3. Further, the heat storage concrete layer 2 is waterproofed, and the water that has permeated from the water permeable concrete 3 is waterproofed by the upper surface of the heat storage concrete layer 2.
In addition, as shown in FIG. 3, the bedrock hot-water bath facility is partitioned into spaces where one person can lie down, and these spaces are continuous horizontally. Bathers lie in their respective spaces and receive heat from the bedrock.

The bedrock 4 is composed of a hornfels single plate having a thickness of several centimeters of 300 mm to 500 mm square, and three bedrocks are arranged at intervals in each bathing space. And when a bather lies on his back, the bedrock is located on the shoulder, waist and legs.
In addition, ceramic pieces 5 and boulders 6 are embedded on both sides of the bathing space and between the bedrock 4 and the bedrock 4. These ceramic pieces 5 and cobblestones 6 may be mixed uniformly in the entire three layers of water-permeable concrete, in addition to the case where they are embedded in the surface.
By the heat from the heat storage concrete layer 2, far infrared rays and negative ions are generated in combination, and a thermal treatment effect is obtained.
The heat of the hot water pipe 1 is stored in the heat storage concrete layer 2 and is conducted through the fine holes of the water permeable concrete 3 to reach the surface. Conventionally, since this concrete layer has a dense structure, heat conduction has not been performed efficiently. However, in the present application, heat conduction efficiency is improved because fine holes are formed.
Although the thickness of the heat storage concrete layer 2 and the water-permeable concrete 3 layer is arbitrary, it is set as the heat storage concrete layer 4cm and the water-permeable concrete layer 6cm as an example.
Although the diameter and arrangement | positioning space | interval of the hot water pipe 1 are arbitrary, it is set as the structure which is arrange | positioned by the heat storage concrete layer at predetermined intervals, and can heat the whole body of a bather uniformly.
When using the bedrock hot-water bath facility of the present invention, the water-permeable concrete 3 is impregnated with water, so that they are evaporated by heat and a mist sauna effect is obtained.
In particular, by impregnating with radium hot spring water, these vapors spread throughout the space, and a mist sauna effect is obtained in which radium vapor is bathed throughout the body.

Here, Hornfels is a contact metamorphic rock (thermal metamorphic rock) formed by volcanic activity. Hornfels used in the present invention is a natural ore discovered at Miyama prefecture and Miyama prefecture and Oita prefecture boundary, which is said to have been produced more than 20,000 years ago, and is mainly produced in the Takachiho region. Hornfels produced in this region has a mysterious energy, and it has been said that when you climbed Takachiho, the stiff shoulders healed and the body lightened. Various studies have found that it is a stone with
The hornfels are stones having a power called super-electromagnetic waves [terahertz waves], and function to release active energy and suppress activated lipids by the action of active water, freshness maintenance, aging, deodorization, and cell revival. In addition to skin beautifying effects, there are various effects such as atopic dermatitis, lifestyle-related diseases such as diabetes, coldness, stiff shoulders, low back pain, and arthritis.

The following effects are known for the hornfels of the present invention.
(1) Far-infrared rays of 4.0 to 14.0 microns are radiated and have a function of activating human cells and promoting metabolism.
(2) This far-infrared ray has an effect of suppressing the formation of lipid peroxide, which promotes blood flow and improves arteriosclerosis, cerebral thrombus, and myocardial infarction.
(3) The function of human leukocytes and lymphocytes is enhanced to improve immune function.
(4) Hornfels also releases 7,500 negative ions / cc, which relieves stress from the refreshing and relaxing effects, stabilizes the autonomic nerves, and enhances the natural healing power inherent in humans.
(5) It has antibacterial and deodorizing effects and deodorizing effects, and is safe from the viewpoint of hygiene.
(6) When it comes into contact with water, it is converted to reducing water, so that the water has an action of preventing oxidation. It also turns water into alkaline. Therefore, when this water is taken up by living organisms, it has the effect of changing waste products and activating or enlarging living organisms.

The water-permeable concrete is obtained by adding a soil improver to solid sand soil and solidifying it. As shown in FIG. 4, the production method is 0.10 m ^{3 of} sand sand soil for 15 kg to 17.5 kg of cement. (10 buckets), 1.8 liters of soil conditioner (SL-1000), 300 to 500 g of hornfels powder, an appropriate amount of water (about 25 liters) added to them, mixed and solidified. is there.

As the soil condition improver, SL1000 manufactured by SL Chemical Laboratory Co., Ltd. is used. This SL1000 is a liquid medicine composed of 64% alkali metal compound, 20% alkaline earth compound, 6% nitrogen compound, and 10% other components (see FIG. 5).
There is a problem that soil containing organic matter, soil with small particles (such as true sand soil), and soil containing oil are not easily solidified with cement alone. Organic matter dissolves in the adhering water around the soil particles, preventing direct contact between the calcium ions, which are the main reactants in the cement setting reaction, and the soil particles, and at the same time negatively acting on the hydration setting reaction. This prevents the solidification and prevents the cement from solidifying.
However, the addition of a soil conditioner promotes the condensation of inorganic components that constitute the soil particles.

In the process of hardening the cement, an aqueous phase to which unstable calcium ion salts such as trilime silicate (3CaO · SiO ₂ ) and trilime aluminate (3CaO · Al ₂ O ₃ ), which are the main components of the cement, are added. Calcium ions are given to the aqueous phase, and as a result, in the aqueous phase that has become alkaline, the mutual hydration reaction proceeds to form a stable calcium salt hydrate.
On the other hand, the soil components include quartz, feldspar, and mica as temporary minerals, and secondary minerals contain organic matter such as humus, which solidifies the soil and cement mixture. It is thought to inhibit. That is, humic acid, which is a main component of humus soil, is a strong acidic substance and reacts with the main component of cement to form calcium humate. This calcium humate inhibits the formation of the alkaline aqueous phase necessary for the hydration reaction of the cement, and is considered to hinder the solidification of the cement.
Since components corresponding to these are blended in SL-1000, the formation of calcium humate is stopped, and the aqueous phase becomes sufficiently alkaline, so that the cement hydration reaction is promoted.
On the other hand, this SL-1000 also reacts with silicon dioxide (SiO ₂ ), aluminum oxide (Al ₂ O ₃ ), etc., which are components of pure sand soil, to form a hydrate and harden the true sand soil. Have.
The characteristics of the cement of the present invention by mixing and solidifying soil and soil conditioner is that the cement-dissolved component combined with the surface of the soil particles generates various hydrates by hydration reaction, and acicular crystals grow. However, it is in the point of connecting the soil particles and increasing the strength. And innumerable continuous pores are generated inside the solidified concrete, and air permeability, water permeability and water retention are generated as a whole.

Next, the bedrock hot bath facility according to the second embodiment is shown in FIGS.
The bedrock thermal bathing facility according to the second embodiment has a configuration in which the hornfels rock bed 4 is spread over the entire floor on which the bather lies, and three layers of permeable concrete are formed on both sides of the bedrock bed 4 spread. is there.
And the hot water pipe 1 is arrange | positioned under the bedrock 4 and the water-permeable concrete 3, and the reinforcement 7, the polyethylene foam heat insulating material 8, and the waterproof sheet 9 are arrange | positioned under the hot water pipe 1. FIG.
The hot water pipe 1 is inserted into the entire floor surface at a predetermined interval, and the heat of the hot water passing through the interior directly reaches the rock mass 4 or the permeable concrete 3 on both sides.
The bedrock hot water bath facility of the present embodiment, like the bedrock hot bath facility of the first embodiment, impregnates the water-permeable concrete 3 with water, thereby evaporating them with heat and obtaining a mist sauna effect.
In particular, by impregnating with radium hot spring water, these vapors spread throughout the space, and a mist sauna effect is obtained in which radium vapor is bathed throughout the body.

The embodiments of the present invention have been described above. However, the specific configuration of the present invention is not limited to the above-described embodiments, and the present invention includes any design changes that do not depart from the spirit of the invention. It is.
As the water-permeable concrete described in the above embodiment, other materials can be used as long as it is a concrete having fine pores in addition to the use of pure sand. For example, the present invention includes the case of using a soil conditioner described in JP-A-2001-303056, JP-A-2002-226254, and JP-A-2001-303053.
Moreover, although it was set as the structure heated by a hot water pipe in the said Example, it is included in this invention even if it is the structure heated using other heating parts, such as an electric heating part.

It is a top view of a bedrock hot bath facility. It is sectional drawing of a bedrock warm bath facility. It is a perspective view of a bedrock warm bath facility. It is a figure which shows the mixing ratio of the raw material used for water-permeable concrete. It is a figure which shows the component of a soil improvement agent. It is a top view of the bedrock hot-heat bath facility which concerns on 2nd Example. It is sectional drawing of the bedrock warm bath facility which concerns on 2nd Example. It is a disassembled perspective view of the bedrock hot-heat bath facility which concerns on 2nd Example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Hot water pipe 2 Thermal storage concrete layer 3 Water-permeable concrete 4 Rock mass 5 Ceramic piece 6 Cobblestone 7 Reinforcement 8 Foamed polyethylene heat insulating material 9 Waterproof sheet

Claims (5)

  A bedrock hot-water bath facility, characterized by a thermal section located under the permeable concrete layer.   The bedrock hot-water bath facility according to claim 1, wherein the water-permeable concrete layer is formed by mixing pure sand and a soil conditioner into cement and solidifying them.   In addition to the cement, sandy sand, and soil conditioner, hornfels powder was mixed, solidified to form a permeable concrete layer, and further, hornfels rock was placed on top of the permeable concrete layer. The bedrock hot-water bath facility according to claim 1 or 2, characterized by the above.   2. A ceramic piece or cobblestone is embedded in the surface of the water permeable concrete layer, and when a bather lies on his back, a bedrock is disposed at least on the shoulder, waist and feet. 2 or 3 bedrock hot water bath facility. The bedrock hot water bath facility according to any one of claims 1 to 4, wherein the water permeable concrete layer is impregnated with water and the vapor of the water obtains a mist sauna effect.