JP3029689U - Flowerpot insoles - Google Patents

Abstract

(57) 【Abstract】 PROBLEM TO BE SOLVED: To radiate far-infrared rays to adjust the temperature of soil to an appropriate temperature and to molecularize water contained in soil to promote absorption of water from roots of plants. SOLUTION: A far-infrared board 100 centering on a carbon fiber cloth 103 that emits far-infrared rays is sandwiched between an upper heat insulating material 110 and a lower heat insulating material 120 via a reflection sheet 104 to form an insole 10. Electrode 1 with an insole 10 laid on the bottom of the plant
By energizing 06, the temperature of the carbon fiber cloth 103 is raised, the far infrared rays are radiated to the soil, the water contained in the soil is vibrated, the temperature of the soil is raised by frictional heat, and the molecularization of water is promoted. The roots of the plants are easily absorbed.

Description

[Detailed description of the device]

[0001]

[Technical field to which the device belongs]

 This device radiates abundant far-infrared rays from the bottom of the flowerpot, decomposes the water molecules in the soil into single molecules, facilitates absorption by the roots of plants, and promotes plant growth. Regarding

[0002]

[Problems to be solved by the device]

 In order to provide a comfortable living environment, more and more plants are placed indoors.In winter, however, plants reduce their water absorption, so maintenance and management of plants in the shade are not possible. was difficult. Therefore, in winter, for potted plants, a method has been adopted to protect the plants by placing an electric heating sheet under the pots to warm the pots themselves. However, this method only raised the soil temperature and activated the roots of plants, and had no further effect.

The problem to be solved by the present invention is to place an insole on the bottom of a flowerpot to radiate far infrared rays to raise the temperature of the soil moderately and to remove water molecules contained in the soil. It is made into a single molecule to improve the absorption of water into the plant and to facilitate the management of potted plants for longer life.

[0004]

[Means for Solving the Problems]

 In order to solve the problem, the insole of the flowerpot of the present invention is provided with a far-infrared radiator, a heating body for heating the radiator, a heat insulating material for holding the radiator, and a heat insulating layer composed of an air layer. The radiator and the bottom plate of the flowerpot are insulated by arranging the heat insulating material so as to face the bottom plate of the flowerpot, and the other heat insulating material is arranged so as to face the soil in the flowerpot. It is equipped with a structure that insulates the soil. Further, a far-infrared reflecting sheet is provided between the far-infrared radiator and the heat insulating material to prevent the far-infrared radiation toward the bottom plate of the flowerpot. As the radiator, carbon fibers having conductivity are used to serve as a heating body, or the ceramic particles are used as a far-infrared radiator. In addition, an electronic electric heater is provided to heat the radiator.

In this way, by arranging a far-infrared radiator on the bottom plate of the flower pot and radiating the far-infrared rays toward the soil, resonance vibration is caused to the water molecules contained in the soil. It is configured to raise the temperature of soil to an appropriate temperature, unravel the clusters formed by the water molecules binding to each other to form a single molecule, which is well absorbed by plants.

[0006]

[Embodiment of device]

 FIG. 1 shows an embodiment of the insole of the flowerpot of the present invention. The insole 10 of the flowerpot is configured such that the far infrared radiation board 100 is held between the upper heat insulating material 110 and the lower heat insulating material 120.

The far-infrared radiation board 100 has a wiring hole 101 arranged at the center, and has a bowl shape, which is a circular shape in this embodiment. The far-infrared radiation board 100 is constructed by stacking an upper coating layer 107 on the upper surface and a lower coating layer 105 on the lower surface around a carbon fiber cloth 103 as a far-infrared radiation body. The upper and lower coating layers 107 and 105 are insulating sheets made of glass fiber and epoxy resin, and are integrally bonded to the carbon fiber cloth 103. At this time, an electrode 106 connected to a power source is wired between the carbon fiber cloth 103 and the upper coating layer 107. Further, a reflection sheet 104 is arranged between the carbon fiber cloth 103 and the lower cover layer 105 to prevent far infrared rays emitted from the carbon fiber cloth 103 from being emitted toward the lower cover layer 105. .

The upper heat insulating material 110 is a circular transparent plate formed of a resin that can transmit far infrared rays such as polypropylene but does not transfer heat, and has a wiring hole 111 at the center thereof. A base material 113 is radially provided on one surface so as to project. The lower heat insulating material 120 is a circular transparent plate made of a resin such as polypropylene that allows far infrared rays to pass through. The lower heat insulating material 120 has a wiring hole 121 formed in the central portion thereof and a base material 123 radially arranged on one surface. It is a plate body that has a protruding heat insulation function. The base material 123 of the lower heat insulating material 120 is the lower surface, the far infrared radiation board 100 is arranged on the upper surface of the lower heat insulating material 120, and the upper heat insulating material 110 is mounted on the upper surface of the far infrared radiation board 100. 113 is placed in contact with the upper surface of the far-infrared radiation board 100. At this time, the wiring holes 121 of the lower heat insulating material 120, the wiring holes 101 of the far-infrared radiation board 100, and the wiring holes 111 of the upper heat insulating material 110 are aligned so as to pass through. The insole 10 thus arranged forms a space at the height of the base plate 103 and an air layer 80 between the far-infrared radiation board 100 and the soil 55 in the pot, and the lower part is laminated on the far-infrared radiation board 100. An air layer 80, which is the height of the base plate 123, is formed between the heat insulating material 120 and the pot bottom plate 51. A thermostat 30 is provided on the upper heat insulating material 110 of the insole 10. The thermostat 30 has a detection unit (not shown) for detecting the temperature of the soil 55 and is connected to a power source.

The insole 10 thus configured is used by being placed on the bottom plate 51 of the bowl 50. The insole 50 is placed by passing the electric wire 20 that communicates with the power source from the ventilation hole 53 of the bottom plate 51 of the pot 50, abutting the base material 123 of the lower heat insulating material 120 to the bottom plate 51 of the pot 50, With the heat insulating material 110 as the upper surface, the soil 55 is placed on the insole 10 and the plant 60 is planted.

Next, the operation of the insole 10 in the bowl 50 will be described. When the electric wire 20 of the insole 10 at the bottom of the bowl 50 is connected to a power source, the conductive carbon fiber cloth 103 generates heat through the electrode 106 and emits far infrared rays. At this time, the heat insulating materials 110 and 120 are arranged through the air layer 80 so that the temperature of the radiation plate 100 is maintained at about 40 to 60 ° C., and the heat from the carbon fiber cloth 103 to the soil or the bottom of the pot is heated. Is configured so that it will not be robbed. The carbon fiber cloth (emitter) 103 at a temperature of 40 ° C. to 60 ° C. radiates far infrared rays centered on a wavelength of about 8 microns. The temperature of the soil above the insole 10 is designed to be kept at an appropriate temperature (about 20 ° C.) by the thermostat 30. Since the reflection sheet 104 is arranged on the lower surface of the carbon fiber cloth 103, the far infrared rays traveling downward are reflected by the reflection sheet 104 to be inverted and concentrated on the soil 55 wrapping the root 63. Since the upper heat insulating material 110 is made of a material having a property of transmitting far infrared rays, absorption loss by the heat insulating material 110 is small. The lower heat insulating material 120 forms an air layer 80 with a certain gap from the bottom plate 51 by the base plate 123 to allow the water at the bottom of the pot 50 to flow down and prevent heat from moving toward the bottom plate 51. . The conductive carbon fiber cloth 103 as a radiator generates heat by energizing the electrode 106, and its temperature rises. As will be described later, the radiation amount of far infrared rays increases in proportion to the fourth power of the temperature (absolute temperature) of the radiator, so the carbon fiber cloth 103 increases the radiation amount of far infrared rays as the temperature rises. . Further, the present invention arranges the heat insulating materials 110 and 120 through the air layer 80 so as to protect the temperature of the carbon fiber cloth 103 so that the heat is not taken from the carbon fiber cloth 103.

As described above, the pot 50 is configured such that the total amount of far infrared rays emitted from the large area of the insole 10 (radiator) is emitted to the soil 55 surrounding the root 63 of the plant 60. The far infrared rays emitted to the soil 55 vibrate water molecules contained in the soil. The shaken water molecules rub against each other and collide with each other to generate heat, raising the temperature of the soil. The thermostat 30 arranged on the upper heat insulating material 110 senses the temperature of the soil 55 and adjusts it to an appropriate temperature, but the carbon fiber cloth 103 as the radiator is thermally shielded from the soil by the upper heat insulating material 110. Therefore, it is kept at a high temperature of about 40 ° C. When the amplitude of the water molecules that start to vibrate increases, the hydrogen bonds between adjacent molecules are broken and the water molecules are decomposed into individual molecules.

[Hydrogen Bonding of Water Molecules] Here, the bonding of water molecules, that is, hydrogen bonding will be described. Liquid water does not exist independently of HOH molecules, but behaves as a unit called a cluster 200 in which several HOH molecules are connected (see FIG. 4). The cause of forming this cluster 200 is the hydrogen bond 210 between adjacent HO. Gaseous water, that is, water vapor, has water molecules 300 floating independently of each other. Therefore, in order to evaporate liquid water into a gas, the hydrogen bond 210 between HO is dissolved. In addition, water molecules cannot be evaporated unless they are unimolecularized to 300 (single moleculed). Normal water does not evaporate even at a temperature of 100 ° C, but evaporates only when it is given 540 calories of energy per gram called "latent heat of vapor", which means that energy is consumed to solve clusters. Because it is done. In order to evaporate, it is necessary to give all the water molecules energy for breaking the hydrogen bond 210, and the amount of this energy varies depending on the degree of the bond, but it is 0.08- It has been elucidated to be 0.35 eV (electron volt). Based on this energy, the energy required to make 1 gram of water into a single molecule is calculated to be about 150 to 444 calories, and most of the energy called "latent heat of vaporization" of water is calculated. It is understood that is consumed to solve the cluster and turn it into a single molecule. Generally, only heating at 100 ° C. is known as a method of giving necessary energy to break the hydrogen bond 210 forming the cluster 200, but water molecules are irradiated by irradiation of far infrared rays. It is also effective to give the vibration energy to.

[Resonance of Water Molecules] ... See FIG. 5. Two hydrogen (H) and one oxygen (O) are bonded to each other, but the bond is not rigid, and is bonded by a spring. It has a flexible bond like. Therefore, when a shock or vibration is applied, the water molecules start resonance vibration. Since the resonance frequency (natural frequency) of water molecules is extremely high, it is generally expressed by wavelength instead of frequency. Those wavelengths are 2.66 microns and 2.73 microns. (All are near infrared rays), 6.27 microns (far infrared rays) and 12.24 cm (2,450 MHz: microwave frequency). Therefore, the molecules of water can be made to resonate by giving an electromagnetic wave having the same frequency as this natural frequency. Here, FIG. 4 shows changes in the vibration of water molecules when an electromagnetic wave having the same number of wavelengths as the natural frequencies of water molecules is irradiated. (A) A state in which water molecules, hydrogen (H) and oxygen (O) are stationary. (B) When irradiated with infrared light having a wavelength of 2.66 microns, hydrogen (H) stretches and vibrates in the direction of oxygen (O 2). (C) When irradiated with infrared light having a wavelength of 2.73 microns, hydrogen (H) rotationally oscillates around oxygen (O 2). (D) When irradiated with far-infrared rays having a wavelength of 6.27 μm, each hydrogen (H) flutters like a flap and exhibits the most vibrating form. (E) When a radio wave of 12.24 cm (2,450 MHz) is irradiated, two hydrogen (H) oscillates up and down with oxygen (O) as the center. Irradiating radio waves to water is dangerous here, so (e) is not general. Of the remaining three natural vibrations, the farthest form of vibration occurs when irradiated with far infrared rays having a wavelength of 6.27 microns. Since the carbon fiber cloth 103, which is this radiator, emits far infrared rays having a wavelength of approximately 8 microns, vibration given to water molecules is large. When the vibration becomes violent and the amplitude increases accordingly, the motion between the oxygen atom and the adjacent hydrogen atom that compose the water molecule becomes relatively violent, so the hydrogen bond 210 naturally breaks and is called cluster 200. The lumps are decomposed and each water molecule becomes an independent molecule 300, ready for evaporation. This is the principle of imparting monomolecular energy to water by far infrared rays.

[Temperature and Wavelength of Radiator] As described above, sufficient far-infrared ray irradiation is required to decompose clusters formed by water molecules. In order to obtain sufficient far-infrared radiation, it is important to select the material of the radiator and secure the radiation area, but the temperature rise of the radiator is also a major factor. Here, the radiation characteristics of infrared rays with respect to temperature will be described (see FIG. 6). As shown in this graph, when the temperature of the radiator is raised, the radiation amount of far infrared rays increases. According to Stefan-Boltzmann's law, radiant energy increases in proportion to the fourth power of the radiator temperature (absolute temperature). Even if a heat-generating and far-infrared radiator is placed at the bottom of the flower pot, the temperature of the radiator does not rise if the heat is taken away by the soil or the bottom of the pot. Therefore, if the temperature of the radiator is raised to a temperature at which a sufficient amount of radiation is obtained, the soil temperature will exceed the optimum temperature for plants. Therefore, it is necessary to insulate the radiator. Also, in order to impart energy to the water molecules contained in the soil to exert its effect, far infrared rays from the radiator must penetrate through the soil and reach a wide range of water molecules. is necessary. From this point, it is not effective to use infrared rays having a shallow reach depth of 4 μm or less, but far infrared rays having a wavelength of 6 μm or more. If the temperature of the radiator is 10 ° C., the radiation amount of far infrared rays having a wavelength of 6 μm or more is about 220 watt / m ² .

On the other hand, since the carbon fiber cloth 103, which is the radiator of the insole 10 of the plant pot 50 according to the present invention, is securely insulated from the soil 55 and the pot bottom 51, the temperature of the radiator is about 40 ° C. Held in. Moreover, since the radiation amount of far infrared rays having a wavelength of 6 microns or more can be obtained at about 350 watt / m ² , the effect of making water into a single molecule becomes large. As a property of unimolecular water ・ It is well absorbed by plant roots. -Do not freeze to -80 ° C.・ Wraps proteins to prevent bacteria from entering and to prevent spoilage. It is known that it absorbs water from the roots of plants, keeps the soil warm, and prevents decay. In this way, the far-infrared radiation platen 10, which is maintained at a temperature of 40 ° C., radiates far-infrared rays having a wavelength of 6 microns or more, vibrates the water molecules in the soil, and causes frictional heat to cause the temperature of the soil to rise. Along with increasing the water content, the water molecules are unimolecularized to improve the absorption of water from the roots of plants, and help the growth of potted plants.

In addition to the configuration of the far-infrared radiation board described above, a far-infrared radiation board having the following configuration also has the same operation and effect. (1) Structure of the far infrared radiation board 10a ... See FIGS. 7 and 8. As the radiator 103a, carbon fiber or ceramic particles are used and are arranged on the glass or epoxy resin insulating sheet 107a. A heating wire (Nichrome wire or the like) 109a is used as a heating element, and is sandwiched between the epoxy resin insulation sheet 107a and the epoxy resin insulation sheet 105a. The far-infrared radiation board 10a thus configured heats up the entire radiation board by energizing the heating wire, and radiates far-infrared rays. (2) Structure of far-infrared radiation board 10b ... See FIGS. 9 and 10. This far-infrared radiation board 10b uses an electronic heater 109b as a heating element. Then, carbon fiber or ceramic particles are used as the radiator 103b provided on the glass or epoxy resin insulating sheet 107b, and the insulating seal 102b is made of epoxy resin or the like on the electronic heating element 109b. The electronic heating element 109b has a temperature adjusting function and can prevent an excessive temperature rise.

[0017]

[Effect of device]

 The insole of the flowerpot of the present invention radiates far infrared rays to make water molecules in the soil into a single molecule. The vibrational friction of water warms the soil and activates the roots of plants, and water molecules are well absorbed by the roots of plants, so that plants can be kept in a healthy state. Further, by disposing the insole in the flower pot, it is possible to facilitate the maintenance and management of the plant in winter and to prolong the life of the plant.

[Brief description of drawings]

FIG. 1 is an explanatory diagram of a structure of an insole.

FIG. 2 is a cross-sectional view for explaining the configuration of a far infrared radiation board.

FIG. 3 is a sectional view of a flowerpot provided with an insole.

FIG. 4 is an explanatory view of the structure of water.

FIG. 5 is a schematic diagram showing a vibration state of water molecules.

FIG. 6 is a graph of far infrared radiation characteristics.

FIG. 7 is a plan view of another far-infrared radiation board.

FIG. 8 is a sectional view taken along line AA of FIG.

FIG. 9 is a plan view of another far-infrared radiation board.

FIG. 10 is a sectional view taken along the line BB of FIG.

[Explanation of symbols]

 10 Insole 20 Electric wire 30 Thermostat 50 Flower pot 51 Pot bottom 60 Plant 80 Air layer 100 Far infrared radiation board 103 Carbon fiber cloth 104 Reflective sheet 105 Lower coating layer 106 Electrode 107 Upper coating layer 110 Upper thermal insulation 120 Lower thermal insulation

Claims (6)

[Scope of utility model registration request] 1. A far-infrared radiator, a heating body for heating the radiator, and a heat insulating layer laminated on the radiator, wherein the radiator is held by the heat insulating layer, and one heat insulating layer of the flower pot is provided. The insole of the flowerpot, which is arranged so as to face the bottom plate and the other heat insulating layer faces the soil of the flowerpot. 2. The heat insulating layer is composed of an air layer and a heat insulating material, and an air layer is arranged between the radiator and the bottom plate of the radiator, and between the radiator and the heat insulating material facing the soil of the flowerpot to keep the radiator warm. Claim 1
Insole of the mentioned flower pot. 3. The heat insulating layer facing the bottom plate of the flower pot is provided with a far infrared reflecting sheet between the far infrared radiator and the heat insulating material to prevent the far infrared radiation toward the bottom plate of the flower pot. The insole of the flowerpot according to claim 1. 4. The insole of a flowerpot according to claim 1, wherein the carbon fiber having conductivity is used as a radiator of far-infrared rays, and it is configured so as to generate electric current and generate heat to serve also as a heating body. 5. The insole of a flowerpot according to claim 1, wherein the ceramic particles are used as a far infrared ray radiator. 6. The insole of the flowerpot according to claim 1, wherein an electronic electric heater is provided as a heating body for heating the radiator.