JP3169913U - Wave space generator - Google Patents

Abstract

To provide a wave space generation device that uses a geothermal heat exchanger to maintain a medium liquid at a predetermined temperature, thereby reducing equipment costs and operation costs, saving energy, and requiring no measures against freezing. BME generation in which a circulation pipe 120 that circulates a medium liquid 20 at a predetermined temperature is provided inside, and a surface is formed of a material containing a radiation material such as far infrared rays whose emissivity at a wavelength of a human body resonance absorption region is a predetermined value or more. The wave space generator 10 that includes the panel 12 and the BME resonance plate 14 provided on the wall 34, the floor 36, the ceiling 38, and the like and that forms the wave space 22 surrounded by the BME generation panel 12 and the BME resonance plate 14 In this case, the underground heat exchanger 16 that exchanges the medium liquid 20 with the underground heat and maintains the medium liquid 20 at a predetermined temperature, and the circulation that circulates the medium liquid 20 between the BME generating panel 12 and the underground heat exchanger 16. And a pump 18. [Selection] Figure 2

Description

The present invention makes efficient use of weak magnetic energy, negative ions and far-infrared rays suitable for humans and animals and plants by using materials that emit weak magnetic energy, negative ions and far-infrared rays from wave stones (Amphibole). The present invention relates to a wave space generation apparatus that can radiate well and make a living space such as a home, a hotel private room, or a medical facility easily and comfortable.

  Far-infrared radiation is said to be good for health because it activates cells and promotes metabolism by resonance absorption of the radiation in the human body, but in order to enjoy such effects, far-infrared radiation It is necessary to be in a radiated space (wave space).

  As a device capable of generating a wave space by far infrared rays, for example, a wave space generating device that constitutes a space surrounded by a far infrared ray generating panel and a far infrared ray resonance plate, as described in Reference 1, for example. There is.

In such a wave space generation device, the medium liquid whose temperature is controlled by the cooling equipment or the hot water supply equipment is circulated in a pipe provided in the far infrared ray generating panel, and the far infrared ray producing panel is adjusted to a predetermined temperature. And far infrared rays are emitted.

Utility Model Registration No. 3163747

  However, in such a conventional wave space generator, the power consumption for controlling the temperature of the medium liquid by heating and cooling is large, and the antifreeze liquid is used as the medium liquid as a countermeasure against freezing in winter. There is a problem that the operation cost of the heat source is high.

The present invention has been made in view of such problems, and by using a ground heat exchanger to maintain the medium liquid at a predetermined temperature, the equipment cost and operation cost are low, and energy saving and anti-freezing measures are taken. An object is to provide an unnecessary wave space generation apparatus.

  In order to achieve this object, the wave space generator according to the present invention is configured as follows. In the present invention, a pipe that circulates a medium liquid at a predetermined temperature is provided inside, and the surface is formed of a material containing a far infrared radiation material (BME radiation material) whose emissivity at a wavelength of the human body resonance absorption region is a predetermined value or more. A far-infrared etc. generating panel (BME generating panel) and a far-infrared etc. resonance plate (BME generating plate) formed on the surface or near the surface with a material containing a radiation material such as far-infrared, etc. In a wave space generator that constitutes a space surrounded by equi-resonant plates, a ground heat exchanger that exchanges heat between the medium liquid and the ground heat and keeps it at a predetermined temperature, and the medium liquid generates far infrared rays, etc. A circulation pump that circulates between the panel and the underground heat exchanger is provided.

  Here, the underground heat exchanger is composed of a sealed container buried underground at a predetermined depth, an introduction pipe for introducing the medium liquid from the far infrared ray generation panel into the upper part of the sealed container, and the medium liquid from the lower part of the sealed container. A discharge pipe that discharges to the circulation pump, and further includes an air vent pipe that supplies the medium liquid to the sealed container and vents the air from the sealed container, and an open / close valve that opens and closes the ground-side end of the air vent pipe.

In addition, the cylindrical airtight container is composed of a cylindrical portion having a central axis arranged in a substantially vertical direction in a state where it is buried underground, an upper end surface portion, and a lower end surface portion, and an introduction pipe, an exhaust pipe and an air vent pipe on the upper end surface portion. Is provided. Furthermore, a cylindrical airtight container is formed with stainless steel or a synthetic resin, and is embedded in a position deeper than 5 m from the ground surface.

  According to the present invention, the medium liquid maintained at a substantially constant temperature using the underground heat exchanger is circulated between the underground heat exchanger and the far infrared ray generating panel (BME generating panel) by the circulation pump. Thus, the far infrared ray generation panel (BME generation panel) can be maintained at a predetermined temperature, and the facility cost and the operation cost for making the wave space generation device always available in a room temperature environment are reduced.

In addition, since the operation of the wave space generation device requires less power to operate a low-power circulation pump for circulating the medium liquid, the conventional wave space generation device that requires cooling facilities, hot water supply facilities, etc. Compared to, energy saving is significant.

Explanatory drawing which shows the whole structure of the wave space production | generation apparatus by this invention in a plane Explanatory drawing which shows the whole structure of the wave space production | generation apparatus by this invention in a cross section Explanatory drawing which shows embodiment of the BME generating panel of FIGS. Explanatory drawing which shows embodiment of the BME resonance plate of FIG. Explanatory drawing which shows embodiment of the underground heat exchanger of FIG.

  In the present application, the three elements of weak magnetic energy, negative ions, and far infrared rays are collectively referred to as BME. For example, in the case of a BME generating panel, it means a panel that generates weak magnetic energy, negative ions, and far infrared rays. It becomes.

  In the description of the embodiments below, each of the BME emitting material, the BME generating panel, and the BME resonance plate corresponds to the emitting material such as far infrared rays, the far infrared emitting panel, and the far infrared resonance plate in the claims. is doing.

  1 and 2 are explanatory views showing the entire configuration of a wave space generating apparatus according to the present invention, FIG. 1 is a plan view, and FIG. 2 is a sectional view. As shown in FIGS. 1 and 2, the wave space generation apparatus 10 of the present invention combines a BME generating panel 12 and a plurality of BME resonance plates 14 in a room 32 of a house 30 to constitute a wave space 22 by BME.

  In the present embodiment, as will be described in detail later, the surface of the wall 32, the floor 36, and the ceiling 38 on the side of the room 32 or the vicinity of the surface constituting the room 32 of the house 30 constitutes the BME resonance plate 14. Yes.

  In the BME generating panel 12, the medium liquid 20 having a substantially constant temperature circulates in a circulation pipe 120 disposed inside the panel, and the panel temperature is maintained at a predetermined temperature. The medium liquid 20 is sucked up by the circulation pump 18 from the underground heat exchanger 16 buried underground, supplied to the BME generation panel 12 through the supply pipe 122, circulated through the circulation pipe 120 in the BME generation panel 12, and then refluxed. It is discharged from the pipe 124 and returned to the underground heat exchanger 16.

  As shown in FIG. 2, the underground heat exchanger 16 is buried underground so that the depth S from the ground surface 50 at the upper end portion is 5 to 5.5 m, which is 5 to 6 m underground. This is because the underground temperature is approximately 15 to 16 ° C. (in the case of the Kanto region) throughout the year, so that the medium liquid 20 can be dispensed with without requiring a heating source or cooling source that requires power. It can always be kept at 15-16 ° C.

  As will be described in detail later, the underground heat exchanger 16 has a diameter of about 30 to 60 cm corresponding to the diameter of a hole that can be drilled by a drill machine (such as an auger drill) used for power pole burying work. Installation work such as excavation and burial can be performed easily, and the installation cost can be kept low.

  The medium liquid 20 only circulates through a sealed pipe having a total lift of about 6 to 7 m, which is returned from the underground heat exchanger 16 to the underground heat exchanger 16 via the circulation pump 18 and the BME generating panel 12. If the amount of circulating water is, for example, about 15 L / min, the power consumption of the circulation pump 18 is about 60 W. That is, the wave space generation device 10 of the present embodiment can be operated at the same cost as a 60 W light bulb.

  Further, since the medium liquid 20 is always kept at 15 to 16 ° C., it is not necessary to use an antifreeze liquid as the medium liquid 20, and in this respect also, the operation cost can be reduced compared to the conventional wave space generation device. . In addition, as the medium liquid 20, tap water is usually used.

  FIG. 3 is an explanatory view showing an embodiment of the BME generating panel 12 used in the wave space generating apparatus 10 of FIGS. 1 and 2, and FIG. 3A describes the internal structure of the BME generating panel 12. FIG. 3B is a cross-sectional view of the BME generating panel 12.

  In FIG. 3A, the BME generating panel 12 is uniformly arranged in parallel with the circulation pipe 120 being bent inside the frame 126 surrounded by a rectangle, and the circulation pipe 120 is disposed inside the frame 126. It is fixed to the support member 128 that is passed to

  From this state, as shown in FIG. 3 (B), the BME generation panel 12 is formed by covering the circulation pipe 120 with aluminum plates 130 from both sides of the frame 126 in which the circulation pipe 120 is disposed. In addition, on the outside of the aluminum plate 130, a paint containing a BME radiation material is baked to form a BME radiation film 132.

  As the BME radiation material, a material that generates electromagnetic waves (far infrared rays) in a wavelength band of at least 4 to 12 μm is used. An electromagnetic wave having a wavelength band of 4 to 12 μm is also called a nurturing light beam, and is a wavelength band that becomes an optimal human body resonance absorption region for animals and plants including humans.

  As the BME radiation material in the present embodiment, amphibole (wave stone) having a far-infrared emissivity of 90% or more in the wavelength band of 4 to 12 μm is used, pulverized into powder, and mixed in the paint for baking coating. is doing.

  As a material for the paint for baking coating, there are acrylic resin type and silicon resin type, and the coating film has a thickness of about 20 to 50 μm. For this reason, about 20% by weight of wave powder, in which wave stone is made into fine powder on the order of several μm, is mixed.

  The reason for using an aluminum substrate for the panel surface of the BME generating panel 12 is to efficiently conduct heat from the circulation pipe 120. Aluminum has a high thermal conductivity of 229 W / (m · k) and is one of the most suitable materials for a panel surface because it is relatively light among metals.

  By utilizing this high thermal conductivity, the surface temperature of the aluminum plate 130 rises quickly due to the temperature of the circulating medium liquid 20. And the film containing the undulating stone formed on the surface of the aluminum plate 130 is set to a uniform temperature, and BME radiation is efficiently performed.

  The BME generating panel 12 of the present embodiment has a structure in which an aluminum plate 130 is stretched on both sides of a frame body 126, and a powder of wave stone is baked and painted on the surface of the frame 126 to form a BME radiation film 132. For example, the frame 126 may be filled with concrete or mortar mixed with wave stone sand or crushed stone as a BME radiation material, and the circulation pipe 120 may be bent and disposed uniformly.

  Concrete and mortar have a low thermal conductivity of 0.9 W / (m · k), and the time to rise to the temperature of the medium liquid 20 circulating through the circulation pipe 120 is slow, but can be used as a heat storage material. Further, if both surfaces of the circulation pipe 120 are sandwiched between wire meshes, the thermal conductivity is improved and the temperature of the panel surface can be made uniform.

  The size of the BME generating panel 12 of the present embodiment is a rectangular parallelepiped (thick rectangle) having a length of about 80 cm, a width of 180 cm, and a thickness of about 6 cm, for example, but the dimensions can be freely changed depending on the installation environment. If the thickness of the circulation pipe 120 is sufficient, the shape need not be rectangular.

  The weak magnetic energy, negative ions and far-infrared rays radiated from the BME generation panel 12 are radiated into the space to form a resonance space by a resonance phenomenon. For this purpose, the BME resonance plate 14 must be installed, A space surrounded by the panel 12 and the BME resonance plate 14 is a wave space 22.

  FIG. 4 is an explanatory view showing an embodiment of the BME resonance plate 14 used in the wave space generation device 10 of FIGS. 1 and 2, and FIG. 4A shows that the BME resonance plate 14 is installed on the wall 34. FIG. 4B shows a configuration installed on the floor 36.

  As shown in FIG. 4 (A), the wall 34 has a gypsum board 142 applied to the crosspiece 42 provided inside the outer wall 40 with the BME resonance sheet 140 sandwiched therebetween. The wallpaper 146 is pasted by the adhesive 144 mixed with the BME radiation material.

  When the BME resonance plate 14 is installed on the ceiling 38 (not shown), the configuration of the wall 34 is substantially the same. In the case of the wall 34 and the ceiling 38, the BME resonance sheet 140, the gypsum board 142, the BME radiation material The BME resonance plate 14 is constituted by the mixed adhesive 144 and the wallpaper 146.

  The BME resonance sheet 140 is an amphibole (wave stone) whose emissivity of far-infrared rays in the wavelength band of 4 to 12 μm is 90% or more, similar to that mixed in the paint for the BME radiation film 132 of the BME generation panel 12. Is a sheet containing wave powder that is pulverized into fine powder.

  As the material of the sheet, when the BME resonance sheet 140 also serves as a moisture-proof sheet, a synthetic resin is desirable, but any material such as paper or nonwoven fabric may be used. In addition, as the BME radioactive material-mixed adhesive 144, an adhesive mixed with wave powder similar to that of the BME resonance sheet 140 is used as a wallpaper cross paste.

  When the BME resonance plate 14 is installed on the floor 36, as shown in FIG. 4 (B), a base material 148 such as a panel is placed by sandwiching the BME resonance sheet 140 between joists 46 provided on the upper side of the beam 44. Further, a flooring 150 such as flooring is provided on the surface of the base material 148. In this case, the BME resonance plate 140 is constituted by the BME resonance sheet 140, the base material 148, and the floor material 150.

  When the floor material 150 is attached to the base material 148 with the BME radioactive material mixed adhesive 144 instead of nailing, the BME resonant plate 140, the base material 148, the BME radioactive material mixed adhesive 144, and the floor material 150 are used to form the BME resonant plate. 14 is configured.

  Further, as another embodiment (not shown) of the BME resonance plate 14, in the case of a structure in which plaster is applied to the inner wall surface of the wall 34, wave stone powder as a BME radiation material is mixed into the plaster, or the ceiling The BME resonance plate 14 using the inner wall surface of the room 32 may be obtained by coating a 38 wood with a fine powder of wave stones, for example, varnish.

  Since the wave space 22 only needs to resonate at a wavelength of 4 to 12 μm, the material on the surface of the BME resonance plate 14 may be different from the material on the surface of the BME generating panel 12, and the content of the wave stone is a material such as plaster or varnish. Can be formulated according to

  Further, the BME resonance plate 14 may have a configuration in which Japanese paper is coated with a paint containing a BME radiation material made of wave stones, and in this case, the BME resonance plate 14 can be freely attached to a wall surface or the surface of furniture.

  The walls, floors, and ceilings have a wide variety of structures. Regardless of the configuration, sheets, adhesives, paints, etc. containing BME radiation material should be used appropriately in the configuration. Thus, the BME resonance plate 14 can be obtained.

  Further, as another embodiment (not shown) of the BME resonance plate 14, the walls 34, the floor 36, and the ceiling 38 do not constitute the BME resonance plate 14 but are independent units. 14 may be installed in front of the wall 34.

  In this case, the BME resonance plate 14 is made of, for example, a BME resonance film formed by baking a powder of wave stones together with a paint on the surface of an aluminum plate, or a concrete or mortar containing a BME radiation material using the wave stones as a raw material. It may be formed.

  The BME resonance plate 14 generates a resonance effect with the far infrared rays emitted from the BME generation panel 12 by the BME radiation material mixed in the sheet, adhesive, paint, plaster, concrete, mortar, etc. The wave space 22 can be formed by arranging in combination.

  The present invention aims to generate a wave space 22 by far-infrared rays, weak magnetic energy and negative ions in a wavelength band of 4 to 12 μm, and is not a cooling / heating device by heat transfer. There is no requirement for using the thermal radiation phenomenon in

  Therefore, the mixed material of the BME radiation material formed on or near the surface of the BME resonance plate 14 does not have to be the same material and content as the mixed material of the BME radiation material formed on the surface of the BME generation panel 12. Appropriate blending ratios of the materials to be mixed with the respective BME emitting materials may be used.

  FIG. 5 is an explanatory view showing an embodiment of the underground heat exchanger 16 of FIGS. 1 and 2, and shows the depth of the underground in which the underground heat exchanger 16 is embedded. The underground heat exchanger 16 according to this embodiment includes a cylindrical sealed container 160 filled with the medium liquid 20, an introduction pipe 168, a discharge pipe 170, an air vent pipe 172, and an opening / closing valve 174.

  The sealed container 160 is made of a material having good thermal conductivity and corrosion resistance, for example, stainless steel, and includes a cylindrical portion 162, an upper end surface portion 164, and a lower end surface portion 166, and the central axis of the cylindrical portion 162 is arranged in a substantially vertical direction. And buried underground.

  The sealed container 160 of the present embodiment is made of a stainless material. However, since the cost is relatively high, a synthetic resin, such as vinyl chloride or polyethylene, which has a low thermal conductivity but has good corrosion resistance and can be manufactured at a low cost. It is also possible to use a thermoplastic resin.

  As described above, the sealed container 160 of the underground heat exchanger 16 has a diameter D of about 30 to 60 cm corresponding to a hole diameter that can be excavated by a drill machine used for utility pole embedding work, and the length of the cylindrical portion 162. The length L is about 150 cm. Moreover, the depth S from the ground surface 50 is buried at a position deeper than 5 m, substantially at a depth of 5 to 6 m.

  The upper end surface portion 164 of the sealed container 160 is provided with an introduction pipe 168, a discharge pipe 170, and an air bleeding pipe 172. The other ends of the introduction pipe 168, the discharge pipe 170, and the air bleeding pipe 172 project to the ground. ing.

  The introduction pipe 168 introduces the medium liquid 20 from the BME generation panel 12 into the upper part of the sealed container 160, and the discharge pipe 170 discharges the medium liquid 20 from the lower part of the sealed container 160 to the circulation pump 18.

  In addition, the air vent pipe 172 supplies the medium liquid 20 to the sealed container 160 and vents air from directly below the upper end portion 164 of the sealed container 160. An open / close valve 174 that opens and closes to the atmosphere is provided at the end of the air vent pipe 172 on the ground side.

  The medium liquid 20 sucked up by the circulation pump 18 from the discharge pipe 170 opened at the lower part in the sealed container 160 is supplied from the supply pipe 122 to the circulation pipe 120 arranged in the BME generation panel 12, and then It flows out from the reflux pipe 124 and flows into the sealed container 160 from the introduction pipe 168 that opens to the top of the sealed container 160.

  The medium liquid 20 returned into the sealed container 160 exchanges heat with underground heat through the wall surface of the sealed container 160 while flowing from the upper part to the lower part. The medium liquid 20 exchanges heat with the aluminum plate 130 of the BME generating panel 12 while circulating through the circulation pipe 120 in the BME generating panel 12, and is at a temperature of 16 ° C. or higher in summer and 15 ° C. or lower in winter. However, in any case, the temperature becomes 15 to 16 ° C., which is the underground temperature, by heat exchange with the underground heat.

  In the present embodiment, the piping returning from the underground heat exchanger 16 to the underground heat exchanger 16 via the circulation pump 18 and the BME generating panel 12 is a sealed piping in consideration of durability and maintainability. When carrying out the present invention, this pipe can be an open pipe.

  Although the embodiment of the wave space generation device 10 according to the present invention has been described above, the resonance of far infrared rays (electromagnetic waves) generated from the BME generation panel 12 which is a functional aspect thereof will be conceptually described below.

  As shown in FIGS. 1 and 2, far-infrared rays emitted from the BME generating panel 12 held at a constant temperature of 15 to 16 ° C. by the underground heat exchanger 16 are absorbed by the BME resonance plate 14. Since the BME resonance plate 14 contains a BME radiation material made of wave stones and has a high emissivity of 90% or more in the far-infrared wavelength range of 4 to 12 μm, the BME radiation of the BME resonance plate 14 Far infrared rays are re-emitted from the material.

  This is a resonance phenomenon, and far infrared rays re-radiated from the BME resonance plate 14 are radiated to other BME resonance plates 14, and the far infrared rays are similarly re-radiated by the resonance phenomenon. Further, the far infrared rays emitted from the BME resonance plate 14 are also emitted to the BME generation panel 12.

  In this way, the emitted far-infrared light is surrounded by the BME generation panel 12 and the plurality of BME resonance plates 14 by causing a resonance phenomenon by the BME generation panel 12 as a generation source and the plurality of BME resonance plates 14. The space becomes a wave space 22 in which wave energy composed of BME (weak magnetic energy, negative ions and far infrared rays) exists.

  The wave space generation apparatus 10 according to the present invention uses a BME radiation material made of wave stone (amphibole) as a raw material, and BME is efficiently radiated on a daily basis, and the wave space in which wave energy exists at high density. The purpose is to form 22.

  That is, since it is not intended to directly adjust the temperature in the room, for example, in the room 32 in which the wave space generation device 10 is installed, a heater is installed and heated as necessary in winter. Alternatively, in summer, a cooling device may be installed to perform cooling.

The present invention is not limited to the above-described embodiment, includes appropriate modifications without impairing the object and advantages thereof, and is not limited by the numerical values shown in the above-described embodiment.

10: Wave space generation device 12: BME generation panel (far infrared, etc. generation panel)
14: BME resonance plate (resonance plate such as far infrared ray)
16: underground heat exchanger 18: circulation pump 20: medium liquid 22: wave space 30: house 32: room 34: wall 36: floor 38: ceiling 40: outer wall 42: crosspiece 44: beam 46: joist 50: ground surface 120 : Circulation pipe 122: Supply pipe 124: Return pipe 126: Frame 128: Support member 130: Aluminum plate 132: BME radiation coating 140: BME resonance sheet 142: Gypsum board 144: BME radiation material mixed adhesive 146: Wallpaper 148: Base material 150: Floor material 160: Sealed container 162: Cylindrical portion 164: Upper end surface portion 166: Lower end surface portion 168: Introduction pipe 170: Discharge pipe 172: Air vent valve 174: Open / close valve

Claims (6)

A far-infrared emission generating panel having a pipe that circulates a medium liquid at a predetermined temperature inside, the surface of which is formed of a material containing a far-infrared emission material having an emissivity at a wavelength of the human body resonance absorption region of a predetermined value or more; A far-infrared resonance plate having a surface or near the surface made of a material containing a radiation material such as infrared, and a wave space generating device that constitutes a space surrounded by the far-infrared emission panel and the far-infrared resonance plate In
A geothermal heat exchanger for exchanging the medium liquid with geothermal heat and maintaining the predetermined temperature,
A circulation pump for circulating the medium liquid between the far infrared ray generating panel and the underground heat exchanger;
A wave space generating device comprising:
The wave space generation device according to claim 1, wherein the underground heat exchanger is
A sealed container buried underground at a predetermined depth;
An introduction pipe for introducing the medium liquid from the far infrared ray generating panel into the upper part of the sealed container;
A discharge pipe for discharging the liquid medium from the lower part in the sealed container to the pump device;
A wave space generating device comprising:
The wave space generator according to claim 2, wherein the underground heat exchanger is
An air bleed pipe for supplying the medium liquid to the airtight container and for releasing air from the upper end of the airtight container;
An open / close valve that opens and closes the ground side end of the air vent pipe;
A wave space generating device comprising:
The wave space generating device according to claim 3, wherein the sealed container is configured by a cylindrical portion, an upper end surface portion, and a lower end surface portion having a central axis arranged in a substantially vertical direction in a state of being buried underground, and the upper end surface portion A wave space generating apparatus comprising the introduction pipe, the discharge pipe, and the air bleeding pipe.
3. The wave space generation device according to claim 2, wherein the sealed container is embedded at a position deeper than 5 m from the ground surface.
  The wave space generation device according to claim 2, wherein the sealed container is made of stainless steel or synthetic resin.

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