WO2011052203A1 - Needle farming method - Google Patents
Needle farming method Download PDFInfo
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- WO2011052203A1 WO2011052203A1 PCT/JP2010/006359 JP2010006359W WO2011052203A1 WO 2011052203 A1 WO2011052203 A1 WO 2011052203A1 JP 2010006359 W JP2010006359 W JP 2010006359W WO 2011052203 A1 WO2011052203 A1 WO 2011052203A1
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- needle
- plant
- farming method
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- plant body
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Images
Classifications
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- A—HUMAN NECESSITIES
- A01—AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
- A01G—HORTICULTURE; CULTIVATION OF VEGETABLES, FLOWERS, RICE, FRUIT, VINES, HOPS OR SEAWEED; FORESTRY; WATERING
- A01G7/00—Botany in general
- A01G7/04—Electric or magnetic or acoustic treatment of plants for promoting growth
-
- A—HUMAN NECESSITIES
- A01—AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
- A01G—HORTICULTURE; CULTIVATION OF VEGETABLES, FLOWERS, RICE, FRUIT, VINES, HOPS OR SEAWEED; FORESTRY; WATERING
- A01G22/00—Cultivation of specific crops or plants not otherwise provided for
Definitions
- the present invention relates to an agricultural technique for functional activation and growth of a living body.
- the elongation force of the living body at that time is said to be about 10 cm, and with the evolution of the conduits and vascular bundles in the central column of the living body, the present living body is also capable of extending and growing more than 100 m above the ground.
- the reason for the evolution is presumed to be the bisection of the body inside and outside. In other words, it can be considered as the construction of a centralized system based on the bipartite structure of plant organisms.
- Plant life is stubbornly defending each role, sharing each role, and growing by growing and growing. Since plants are undifferentiated organisms, Australia's Harborland advocated the totipotency of plant life in 1958. That is, it is generally understood that all plant cells are the same. This is why it is now called a stem cell. As one proof, 1978 German Melhijas grew potatoes (potato roots and tomato roots). It was amazing news internationally.
- the balance of plant life is “dynamic equilibrium”, and “water balance” is important. In addition to this, constant balance is essential. For this reason, the internal and external equilibrium potentials of the living body are regarded as one means, and the current carrying body (screw length of about 35 to 40 mm) is inserted in the vicinity of the grafted part (root) of the cedar body to provide chest height and grounding. When the electric potential between them was measured, it was the appearance of a totally astonishing potential that increased from 220 mV before inserting the screw to 800 mV. From that assumption, the second stage screw was inserted from the opposite side of the screw insertion, and the chest height was measured again. As a result, it increased to about 1130 mV, and it was completely amazing.
- the growth of the living body is one of the keywords of the growth rate, which is the expansion of the potential (voltage) of the self-living body. is there.
- the “point” similar to the meridians and acupuncture points in the Yin Yang five-part theory based on Oriental medicine was born from various experimental backgrounds, and the needle farming method of the present invention was conceived from the results. is there.
- the present invention aims to provide an agricultural method for promoting the fixation of carbon dioxide by regenerating and activating forests.
- the inventor has anticipated the current global warming phenomenon from about 30 years ago, and has been diligently researching functional improvement measures for plants as a countermeasure.
- functional improvement measures for plants were conducted on the presence or absence of defects in the living body, and through trial and error, functional improvement of the living body produced living body growth and constant dynamic equilibrium. They obtained the knowledge that they can expect a growth potential of about 30-40%.
- the present invention has been achieved.
- the implementation effect is determined by comparing the measurement value before the implementation and the measurement value after the implementation.
- the bifurcated structure means that the outer wall of the central column is strengthened, and the expansion of the water absorption force generates the rising force of underground water, and the extension effect reaches 100m with the evolution of the conduit and vascular bundle in the central column.
- the outer wall in the living body becomes thicker and the balance of the living body is deteriorated, and therefore, the living body is connected to the central column and the skin part (formation layer, etc.) through the living body. Therefore, it was decided to balance the polar potential of the body and to construct a biological balance.
- the needle farming method of the present invention is a farming method for increasing the growth of a plant body provided with a cusbury zone, and has an internal high potential inside the cusbury zone of the plant body and an external low potential on the epidermis side.
- a current-carrying body is connected or planted into the plant body from the outer skin side at a substantially right angle, the plant body body is selected by selecting a site where the potential of the inserted or driven site increases or decreases from the rate of change of a predetermined threshold.
- the high potential part inside the plant body and the low potential part outside the plant body are directly connected by the current-carrying body, or are penetrated at a substantially right angle from the outside of the living body to the outside on the opposite side, The side potential is increased.
- An electrical conductor that connects the high-potential part near the conduit of the angiosperm plant body and the low-potential part on the epidermis side reduces the potential difference between the inside and outside of the plant body to achieve balanced potential distribution, It encourages activation and growth.
- a site where the current-carrying body is inserted or driven a site where the potential increases or decreases from the rate of change of the predetermined threshold is selected and used as a plant acupuncture point.
- the electrical conductor that connects the inside and outside of the plant body is inserted or driven into the plurality of acupuncture points to further increase the potential on the epidermis side of the plant body.
- the site where the potential increases or decreases from the rate of change of the predetermined threshold is a site where the potential increases 2 to 4 times or decreases 1/2 to 1/4 in 1 to 24 hours, It is often seen at the branching site of branches and leaves. This is a site where cell proliferation is active.
- Plant organisms are angiosperms and their seedlings.
- the reason for including seeds and seedlings is that the vitality of living bodies that grow from seedlings obtained from plant living bodies subjected to the needle farming method of the present invention is excellent.
- the current-carrying body is preferably selected from a conductive needle, a conductive pin, a conductive screw, a conductive nail, and a conductive staple.
- a member having a pointed tip is used as a member of the current-carrying member.
- the current-carrying member may be a metal wire or carbon fiber wound around the long axis of a hard needle-like member. Since current-carrying bodies such as metal wires and carbon fibers cannot be inserted into a plant body, they are wound around a rigid needle-like member.
- the current-carrying body is a diode or a transistor, and a diode or a transistor in which two terminals of the transistor are inserted into a plant body can be suitably used.
- the transistor is preferably a phototransistor, and two terminals of the phototransistor are inserted into a plant body.
- a weak potential difference occurs between two terminals due to light. This weak potential is applied to the plant body.
- the above diode is preferably a photodiode or a light emitting diode, and two terminals of the diode are inserted into a plant body.
- the potential generated from the photovoltaic power generation transistor is applied to the plant body.
- a conductive needle, a conductive pin, a conductive screw, a conductive nail, a conductive staple, or a metal wire or carbon fiber in the major axis direction of a rigid needle-shaped member It is a preferred embodiment that a current-carrying body composed of a wound body is passed through the plant body from the outside to the opposite side at a substantially right angle and a voltage of 1.5 to 100 V is applied to both ends of the current-carrying body. .
- a voltage of 1.5 to 100 V, preferably 1.5 to 10 V, more preferably 1.5 to 5 V is applied to both ends of the current-carrying body.
- a conductive needle, a conductive pin, a conductive screw, a conductive nail, a conductive staple, or a metal wire or carbon fiber in the major axis direction of a rigid needle-shaped member Two current-carrying members composed of wound ones are inserted from opposite directions at right angles from the periphery of the stem of the plant body, and a voltage of 1.5 to 100 V is applied between the two current-carrying members. Is a preferred embodiment. A voltage of 1.5 to 100 V, preferably 1.5 to 10 V, more preferably 1.5 to 5 V is applied between the two electric conductors.
- Two current-carrying bodies made up of wound ones are inserted from opposite directions at a right angle from the periphery of the stem of the plant body, and two terminals of the phototransistor or the photovoltaic power generation transistor are connected to the two current-carrying bodies. It is a preferable aspect to join.
- the groove is cut along the axial direction of the electrification body selected from the electrification needle, the electrification pin, the electrification screw, the electrification nail, and the electrification staple. .
- the energizing member of the present invention is an energizing body used in needle farming, and is selected from an energizing needle, an energizing pin, an energizing screw, an energizing nail, and an energizing staple, and along the axial direction. The groove is cut.
- the needle farming method of the present invention is very simple and easy, but not as easy as anyone can think of. In other words, it took about 30 years since the pine wilt incident that occurred in Japan to reach the present invention.
- the fixation rate of carbon dioxide against the current global warming is fixed at an increase of 40% in the needle farming method of the present invention, compared to about 68 kg per year of 35-year-old cedar trees specified by the Ministry of Agriculture and Water.
- hay fever disorders caused by trees have spread internationally.
- the needle farming of the present invention has improved by about 80%.
- the forest will be improved to a well-organized forest that is more than thinned, and carbon dioxide fixation will be promoted. Is done.
- the natural environment will be improved with the improvement of forests without pollen.
- FIG. 1 Top view of the needle farming needle needle attached to the plant body Needles using semiconductors attached to plant organisms
- the functional improvement ability of the plant body by the needle farming method of the present invention is the suppression (alloreversity) of the living body in addition to the vitality and activation force of the living body.
- the plant's ability to suppress plants is all about root system growth. That is, the growth of lateral roots, branch roots, and root hairs due to the east of the central column and the epidermis side is extremely promoted. This is because it improves to 100 times. (The current contrast is 1 to 3 to 5.)
- This suppression pressure causes the action of suppressing (withering) other living root systems and non-pollen cedar.
- FIG. 1 has shown the top view of the conductive needle of the needle farming method attached to a plant biological body. As shown in FIG.
- FIG. 1 a ring-shaped knob portion 5 is provided on a conductive needle 6 and is attached via a crimp terminal 12.
- FIG. 2 has shown the needle
- a needle using a semiconductor is obtained by bonding a conductive needle 6 to each of two terminals of a semiconductor 4 such as a transistor or a diode with a crimp terminal 12.
- Elongation growth of trees is said to be up to two-thirds of the average life of trees, and hypertrophic growth is said to be up to life.
- needle farming was carried out on trees for two months, October and November.
- the needle farming method of the present invention it is possible to easily find an acupuncture point (acupuncture point) from which a fruit with excellent quality can be harvested and to stimulate the acupuncture point (acupuncture point) by simply inserting a living body stimulation needle into the stem. is there.
- the polar potential (electric field) of each whole plant is its own biopotential (medium and living stem) is a kind of index indicating the vitality and growth potential of each living body.
- biopotential medium and living stem
- the acupoints and meridians are common or symbiotic acupoints.
- a needle, pin, staple, nail, screw, or the like is inserted or driven into each such acupoint and a voltage is applied to the inside or outside of the living body to bind it, the potential of the plant living body is 1 hour to 2 times in 24 hours. Increase the potential by 4 times. Such potential increase is an index of suppression pressure.
- Fruit vegetables such as peppers, eggplants, tomatoes, etc. are deformed fruit vegetables when the potential is increased in the case of the acupuncture slipping, and the biological balance is deteriorated.
- FIG. 3 shows a state where a needle connected to a photodiode is attached to a plant body (tomato).
- 1 is a tomato tree
- 8 is a conductive pin
- 4 is a semiconductor, specifically a photodiode.
- the conductive pins 8 are inserted into a plurality of places.
- two terminals of the photodiode which is the semiconductor 4 are connected to a tomato stem and a medium (earth).
- FIG. 4 shows a state where a needle connected to a photodiode is attached to a plant body (cabbage). Needles connected to the two terminals of the photodiode are inserted into the plant body and the culture medium, respectively. Therefore, a weak voltage is applied between the plant body and the culture medium.
- 2 is a cabbage leaf
- 9 is a fill
- 4 is a semiconductor, specifically a photodiode. The two terminals of the photodiode which is the semiconductor 4 are connected to the cabbage stem and the culture medium (earth).
- FIG. 5 shows a state where a needle connected to a photodiode is attached to a plant body (tree). Needles connected to the two terminals of the photodiode are inserted into the plant body and the culture medium, respectively. Therefore, a weak voltage is applied between the plant body and the culture medium.
- 3 is a tree
- 8 is a conductive pin
- 4 is a semiconductor, specifically a photodiode. The conductive pins 8 are inserted into a plurality of places.
- the two terminals of the photodiode, which is the semiconductor 4 are connected to the conductive screw 7, and the two conductive screws 7 are inserted from opposite directions at a substantially right angle from the periphery of the plant biological stem.
- FIG. 6 shows a state in which a needle connected to a photodiode is inserted in order to obtain an abnormal body of a seedling in a plant body (acorn). Needles connected to the two terminals of the photodiode are inserted into the plant body and the culture medium, respectively. Therefore, a weak voltage is applied between the plant body and the culture medium.
- 10 is an acorn
- 6 is a conductive needle
- 4 is a semiconductor, specifically a photodiode.
- the conductive needle 6 is inserted into one place. This may be in multiple places.
- one terminal of the photodiode which is the semiconductor 4 is connected in series with the conductive needle. The other is connected to the ring-shaped knob portion 5 via the crimp terminal 12.
- FIG. 8 shows a circuit configuration diagram of a transistor for explaining a needle connected to a semiconductor.
- 22 is a three-terminal transistor, 22 is an applied power supply connected to the gate terminal, 23 is a volume resistor, 24 is a positive terminal connected to the drain terminal, and 25 is a negative terminal connected to the source terminal. is there.
- the herbaceous plant body is a pot used as a control pot by transplanting selected seedlings of various seedlings using a pen containing a non-fertilizer medium as a method for carrying out growth using a penetrating needle. Were used for comparison. In each pot, the growth of seedlings was confirmed 20 days after transplanting, and the growth difference of each port was compared.
- FIG. 7 is a diagram showing a state in which vegetables (lettuce, green pepper, loofah) are transplanted into a pot medium, and a needle connected to a photodiode is inserted and grown. Needles connected to the two terminals of the photodiode are inserted into the plant body and the culture medium, respectively. Therefore, a weak voltage is applied between the plant body and the culture medium.
- 15 is a potted plant (pot)
- 11 is a needle connected to the same semiconductor as in FIG. 6, 14 is a photodiode
- 13 is at the bottom of the potted plant (pot), and is connected to the medium. It is a conductive screw.
- Needle farming can contribute to the suppression of global warming. This is because the bioactivity of the plant body can be improved by the needle farming method.
- the plant living body has a function of fixing carbon dioxide and releasing oxygen (supplying oxygen to animals). For example, according to a material published by the Forestry Agency of the Ministry of Agriculture, Water and Agriculture, it is described that the average tree of a 35-year-old cedar tree fixes about 68 kg of carbon dioxide annually.
- the reforestation of the conventional farming method has an income per Ha of -4.3 million yen
- the reforestation of the B needle farming method has a revenue of +1.9 million yen per ha.
- the growth of the root system by the needle farming method makes it possible to produce a plant body in which the growth of the root system in the underground part is healthy and is suppressed (alorepathy) regardless of whether it is a straight root or a whisker root.
- Botanist Daitoma argues that the surface area of the underground part is preferably 100 to 150 times that of the surface part (branches and leaves) of the above part.
- the 21 dollar farming method of the present invention is based on the three Yin Yang theory related to plant life as an organism living on the same earth, elucidating the Yin Yang five theory based on the view of nature in Oriental medicine. It is a creation and construction of acupoints of plants that are meridians and acupuncture points.
- Acupuncture point measurement of plant living body Using a commercially available voltmeter or a commercially available ammeter, a method of measuring a culture medium (earth) and a living body chest value (position about 130 cm above the ground) to determine acupuncture points of a plant living body. explain. First, the biological breast high is measured with a + lead bar, and the medium is measured with a-lead bar. There is a part where the potential difference changes when it is inserted in the vicinity of the plant body with the medium (earth) as a reference. And the position where the potential difference becomes maximum is determined as the acupuncture point. Thus, the meridian is obtained from the change rate of the potential difference before and after the measurement.
- the needle farming method of the present invention includes trees, vegetables, flower trees, fruit trees, natural trees, artificial forests, forests, parks, shrines, ceremoni temples, schools, street trees, hydroponics, cuttings cultivation, cuttings, cut flowers, seedlings, senescence Useful for revitalizing trees, rejuvenating old trees, and increasing fruit yields. Moreover, it is useful for the method of aiming at the production expansion by the plant factory using a pot, a container, etc. It is also useful for disease treatment by plants in general. Furthermore, it is useful for the development of new seedlings.
Abstract
Description
従って、現下の地球的な温暖化の削減や温暖に起因する農作物に対応するアロレパシー的な農業技術として、本件特許の出願に至ったのである。 Based on the above means and methods, when a growth measurement band is set at the chest height, which is used as a method for measuring plant organisms, and trees of the same, same species, and age are measured, the amount of growth is about 30-50%. Was found to appear.
Therefore, the present patent application has been filed as an allopathic agricultural technology for current global warming reduction and crops caused by warming.
本発明のニードル農法は、実施前の測定値と実施後の測定値の比較を以って、その実施効果の判定を行う。即ち、植物生体の培地(同所、同地、同種)の測定において、植物生体の胸高置(地上約130cm)と培地との間の杉の木や松の木をそれぞれ数1000本の測定と、野菜のトマトやピーマンをそれぞれ数1000本の測定を以って、本件の植物生体の極性的電気の測定方法の効率効果を確認した上で、本発明のニードル農法を申請するに至ったのである。 There are no measuring instruments or measuring methods in the current agricultural industry other than determining the growth potential (potential) of each organism by measuring the height of the plant's breast and the medium (earth), depending on the magnitude of the potential difference. In the situation of not doing so, the present invention has been achieved.
In the needle farming method of the present invention, the implementation effect is determined by comparing the measurement value before the implementation and the measurement value after the implementation. That is, in the measurement of plant biological medium (same place, same place, same species), several thousand cedar trees and pine trees between the chest height of the plant biological body (about 130 cm above the ground) and the medium are measured, and vegetables The number of thousands of tomatoes and bell peppers was measured, and after confirming the efficiency effect of the method for measuring the polar electricity of the plant body of the present case, the present inventors have applied for the needle farming method of the present invention.
電位が所定閾値の変化率より増加もしくは減少する部位とは、具体的には、電位が1~24時間中に2~4倍に増加もしくは1/2~1/4に減少する部位であり、枝葉の分岐する部位に多くみられる。これは細胞増殖が活発な部位である。 Here, it is preferable that the electrical conductor that connects the inside and outside of the plant body is inserted or driven into the plurality of acupuncture points to further increase the potential on the epidermis side of the plant body.
Specifically, the site where the potential increases or decreases from the rate of change of the predetermined threshold is a site where the potential increases 2 to 4 times or decreases 1/2 to 1/4 in 1 to 24 hours, It is often seen at the branching site of branches and leaves. This is a site where cell proliferation is active.
通電体の部材としては、植物生体に差し込む際の作業性を考慮し、先端の尖った形状のものを使用する。 The current-carrying body is preferably selected from a conductive needle, a conductive pin, a conductive screw, a conductive nail, and a conductive staple.
In consideration of workability when inserting into a plant body, a member having a pointed tip is used as a member of the current-carrying member.
また、樹木による花粉症障害は、国際的に及んでいる。しかしながら、本発明のニードル農法によれば、約80%も改善したという非常に驚くべきデータもある。
更に、本発明のニードル農法によれば、森林の再生林も可能である。即ち、現下のひょろひょろ森林木を選抜して、ひょろひょろ木に、本発明のニードル農法を実施すると、ひょろひょろ木は二年以内に倒木して肥料化する。即ち、本発明のニードル農法の実施を施した木は、二年後には制圧木に成長するために、森林内は間伐実施以上の整理された森林に改善されると同時に二酸化炭素の固定が促進される。加えて花粉体のない森林の改善に伴う、自然環境の改善が図られる。 The fixation rate of carbon dioxide against the current global warming is fixed at an increase of 40% in the needle farming method of the present invention, compared to about 68 kg per year of 35-year-old cedar trees specified by the Ministry of Agriculture and Water.
In addition, hay fever disorders caused by trees have spread internationally. However, there is also very surprising data that the needle farming of the present invention has improved by about 80%.
Furthermore, according to the needle farming method of the present invention, it is possible to regenerate the forest. That is, if the present forest tree is selected and the needle farming method of the present invention is applied to the tree, the tree will fall into fertilizer within two years. In other words, since the trees that have been subjected to the needle farming method of the present invention will grow into controlled trees in two years, the forest will be improved to a well-organized forest that is more than thinned, and carbon dioxide fixation will be promoted. Is done. In addition, the natural environment will be improved with the improvement of forests without pollen.
即ち、中心柱と表皮サイドの結東による側根、支根、根毛の増殖は、極度に促進するから、生体の地上部と地下部 (根部)との表面積の対比を地上1に対し、地下50~100倍に改善するからである。(現下の対比は、1対3~5)この制圧力が、他の近傍生体根系を制圧(枯らす)作用や無花粉スギの起因となる。 (1) The functional improvement ability of the plant body by the needle farming method of the present invention is the suppression (alloreversity) of the living body in addition to the vitality and activation force of the living body. The plant's ability to suppress plants is all about root system growth.
That is, the growth of lateral roots, branch roots, and root hairs due to the east of the central column and the epidermis side is extremely promoted. This is because it improves to 100 times. (The current contrast is 1 to 3 to 5.) This suppression pressure causes the action of suppressing (withering) other living root systems and non-pollen cedar.
かかる生体電位の平衡を求める理由から生まれたのが、植物生体の内外の結合である。この結合方法について、試行錯誤の末に生まれたのが、本発明のニ一ドル農法である。
図1は、植物生体に取り付けるニードル農法の通電性針の平面図を示している。図1に示すように、通電性の針6にリング状のツマミ部5が設けられ、圧着端子12を介して取り付けられている。
また、図2は、植物生体に取り付ける半導体を用いた針を示している。図2に示すように、半導体を用いた針とは、トランジスタやダイオードなどの半導体4の2端子にそれぞれ通電性の針6を圧着端子12で接合させたものである。 (2) The potential in the vicinity of the central pillar of the plant body and the potential in the vicinity of the external cortex are approximately 150 to 200 mV in the vicinity of the central pillar (there is a difference depending on the type of plant body), all of which are caused by the central pillar. It seems that it was born from the evolutionary strong wall structure of the outer wall (such as the Kasbury zone).
The reason why such a bioelectric potential balance is sought is the connection inside and outside the plant body. This combination method was born after trial and error in the single-agricultural method of the present invention.
FIG. 1: has shown the top view of the conductive needle of the needle farming method attached to a plant biological body. As shown in FIG. 1, a ring-shaped
Moreover, FIG. 2 has shown the needle | hook using the semiconductor attached to a plant biological body. As shown in FIG. 2, a needle using a semiconductor is obtained by bonding a
例えば、緩除成長期、直線的成長期、成長終止期の各システムがあり、この間に多くの植物ホルモンが関与している。即ち、成長過程でのホルモン移動と組み合わせやそのタイミングが肝要である。例えば、細胞肥大にはジベレリンやオーキシン、果実の成熟には、エチレンやアブシジン酸が増加する。即ち、細胞分裂->細胞肥大->成熟の過程に各刺激が味覚や糖度を促進するシステムが必要である。本発明のニードル農法によれば、生体の刺激針を茎に1本差し込むのみで、品質の優れた果実が収穫できる経穴(ツボ)を容易に見つけることができ、経穴(ツボ)を刺激できるのである。 (4) Fruit growth and hormonal relationships are closely related to taste, sugar content, etc., but there are differences in each growth system depending on the type. In addition, the growth of cell division fruit and hormonal relations are closely related to taste and sugar content, but there are differences in each growth system depending on the type.
For example, there are slow growth, linear growth, and growth end systems, and many plant hormones are involved in this system. In other words, the combination and timing of hormonal movement in the growth process are essential. For example, gibberellin and auxin increase in cell hypertrophy, and ethylene and abscisic acid increase in fruit ripening. That is, there is a need for a system in which each stimulus promotes taste and sugar content in the process of cell division-> cell hypertrophy-> maturation. According to the needle farming method of the present invention, it is possible to easily find an acupuncture point (acupuncture point) from which a fruit with excellent quality can be harvested and to stimulate the acupuncture point (acupuncture point) by simply inserting a living body stimulation needle into the stem. is there.
かかる各ツボに、針、ピン、ステップル、釘、ネジ等を差し込み、或いは、打ち込み、生体の内外に電圧が印加され結着すると、植物生体の電位は1時問~24時間中に2倍~4倍に電位アップする。かかる電位アップは、制圧力の指標である。
一方、その反応がない場合は、ツボはずれである。ピーマン、ナス、トマト等果菜は、ツボはずれの場合に電位アップさせると、変形果菜に及び、生体バランスが悪化することになる。 (5) The polar potential (electric field) of each whole plant is its own biopotential (medium and living stem) is a kind of index indicating the vitality and growth potential of each living body. There are many acupoints in plant organisms. The acupoints and meridians (acupoints) are common or symbiotic acupoints.
When a needle, pin, staple, nail, screw, or the like is inserted or driven into each such acupoint and a voltage is applied to the inside or outside of the living body to bind it, the potential of the plant living body is 1 hour to 2 times in 24 hours. Increase the potential by 4 times. Such potential increase is an index of suppression pressure.
On the other hand, when there is no reaction, the point is off. Fruit vegetables such as peppers, eggplants, tomatoes, etc. are deformed fruit vegetables when the potential is increased in the case of the acupuncture slipping, and the biological balance is deteriorated.
図7において、15は鉢植え(ポット)であり、11は図6と同様の半導体と接続された針であり、14はフォトダイオードであり、13は鉢植え(ポット)の底にあり、培地と繋がっている通電性ネジである。 FIG. 7 is a diagram showing a state in which vegetables (lettuce, green pepper, loofah) are transplanted into a pot medium, and a needle connected to a photodiode is inserted and grown. Needles connected to the two terminals of the photodiode are inserted into the plant body and the culture medium, respectively. Therefore, a weak voltage is applied between the plant body and the culture medium.
In FIG. 7, 15 is a potted plant (pot), 11 is a needle connected to the same semiconductor as in FIG. 6, 14 is a photodiode, 13 is at the bottom of the potted plant (pot), and is connected to the medium. It is a conductive screw.
従って、ニードル農法の実施により、二酸化炭素の年間固定量が68kgから100kgに1.5倍に改善したと仮定すると、下記の表4,表5のような節減効果が期待できることになる。ここで、間伐費用として、人件費は、1ヶ月1人30万円としている。また、1Haに森林木(スギ)は約2500本生えているとしている。 For the purpose of comparing with the average tree of this 35-year-old cedar tree, 40-year-old cedar tree was selected and used as a comparison tree, and needle farming was repeated. It was 100 kg.
Therefore, assuming that the annual fixed amount of carbon dioxide has improved 1.5 times from 68 kg to 100 kg by the implementation of the needle farming method, the saving effects shown in Tables 4 and 5 below can be expected. Here, as the thinning cost, the labor cost is 300,000 yen per person per month. In addition, about 2500 forest trees (cedar) grow on 1 Ha.
かかる埋由からニードル農法による実験を重ねることで、根系の増殖が可能になった。即ち、側根の経穴(ツボ) を探索し、そのツボに釘や針などを打ち込むと、約1カ月で支根が活性化して根毛が一挙に増殖して表面積が一拳に増加することがわかった。
これは、地下部の養水分の吸引力が容易化され、地上部の要求に即刻対応するシステムが創出されるのである(シンク-ソース論の完成)。ニードル農法を行ったことによる恒常的な動的平衡、すなわち、生体バランスによる効果である。 (8) The growth of the root system by the needle farming method makes it possible to produce a plant body in which the growth of the root system in the underground part is healthy and is suppressed (alorepathy) regardless of whether it is a straight root or a whisker root. Botanist Daitoma argues that the surface area of the underground part is preferably 100 to 150 times that of the surface part (branches and leaves) of the above part.
By repeating experiments using the needle farming method based on such burial conditions, it became possible to grow the root system. In other words, when searching for acupoints on the lateral root and driving a nail or a needle into the acupuncture point, it is found that the root is activated and the root hair grows all at once and the surface area increases rapidly in about one month. It was.
This simplifies the suction of the nutrients in the underground and creates a system that responds immediately to the requirements of the ground (sink-source theory completed). This is the effect of the constant dynamic equilibrium, that is, the balance of the living body by performing the needle farming method.
市販電圧計もしくは市販の電流計を用いて、培地(アース)と生体胸高値(地上130cm程度の位置)を測定し植物生体の経穴を決定する方法について説明する。まず、+リード棒で生体胸高値を、-リード棒で培地を測定する。培地(アース)を基準として植物生体の近傍に差し込むと電位差が変化していく部位がある。そして、その電位差が極大となる位置を経穴と決定する。このように、測定実施前と測定実施後の電位差の変化率をもって、その経絡を求めるのである。 (11) Acupuncture point measurement of plant living body Using a commercially available voltmeter or a commercially available ammeter, a method of measuring a culture medium (earth) and a living body chest value (position about 130 cm above the ground) to determine acupuncture points of a plant living body. explain. First, the biological breast high is measured with a + lead bar, and the medium is measured with a-lead bar. There is a part where the potential difference changes when it is inserted in the vicinity of the plant body with the medium (earth) as a reference. And the position where the potential difference becomes maximum is determined as the acupuncture point. Thus, the meridian is obtained from the change rate of the potential difference before and after the measurement.
2 キャベツ
3 樹木
4 半導体
5 ツマミ部
6 通電性針
7 通電性ネジ
8 通電性ピン
9 盛り土
10 ドングリ
11 半導体と接続された針
12 圧着端子
13 通電性ネジ
14 フォトダイオード
15 鉢植え(ポット)
21 3端子トランジスタ
22 印加電源
23 ボリューム抵抗
24 プラス端子
25 マイナス端子
DESCRIPTION OF
21 Three-
Claims (14)
- カスバリー帯を備える植物生体の成長増大を図る農法であって、
植物生体のカスバリー帯より内側の内部高電位と表皮サイドの外部低電位とを結ぶ通電体を、外部の表皮サイドより植物生体に略直角に差し込み又は打ち込みした場合に、該差し込み又は打ち込みした部位の電位が所定閾値の変化率より増加もしくは減少する部位を選抜し植物生体の経穴として、植物生体内部の高電位部と植物生体外部の低電位部とを前記通電体で直結させて、又は、生体外部より反対側の外部まで略直角に貫通させて、植物生体の表皮サイドの電位を増大させることを特徴としたニードル農法。 A farming method for increasing the growth of plant organisms with a cusbury zone,
When a current-carrying body that connects the internal high potential inside the plant body's Casbury zone and the external low potential on the epidermis side is inserted or driven into the plant body from the external epidermis side at a substantially right angle, A site where the potential is increased or decreased from the rate of change of the predetermined threshold is selected as a plant acupuncture point, and a high potential part inside the plant body and a low potential part outside the plant body are directly connected by the current-carrying body, or the living body A needle farming method characterized by increasing the potential on the epidermis side of a plant body by penetrating from the outside to the outside on the opposite side at a substantially right angle. - 所定閾値の変化率は、差し込み又は打ち込みした部位の電位が1~24時間中に2~4倍に増加若しくは1/2~1/4に減少する部位であることを特徴とした請求項1に記載のニードル農法。 2. The change rate of the predetermined threshold is a portion where the potential of the inserted or driven-in portion increases 2 to 4 times or decreases 1/2 to 1/4 in 1 to 24 hours. The described needle farming method.
- 植物生体の内外を結ぶ前記通電体は、複数の前記経穴に差し込まれ又は打ち込まれ、植物生体の表皮サイドの電位を更に増大させたことを特徴とした請求項1又は2に記載のニードル農法。 3. The needle farming method according to claim 1, wherein the current-carrying body connecting the inside and outside of the plant body is inserted or driven into the plurality of acupuncture points to further increase the potential of the epidermis side of the plant body.
- 前記植物生体は、被子植物およびその種苗であることを特徴とした請求項1又は2に記載のニードル農法。 The needle farming method according to claim 1 or 2, wherein the plant organism is an angiosperm and a seedling thereof.
- 前記通電体は、通電性針、通電性ピン、通電性ネジ、通電性釘、通電性ステップルから選択されるものであることを特徴とした請求項1又は2のニードル農法。 The needle farming method according to claim 1 or 2, wherein the current-carrying body is selected from a conductive needle, a conductive pin, a conductive screw, a conductive nail, and a conductive staple.
- 前記通電体は、金属線あるいは炭素繊維を硬質性の針状部材の長軸方向に巻きつけたものであることを特徴とした請求項1又は2のニードル農法。 The needle farming method according to claim 1 or 2, wherein the current-carrying body is formed by winding a metal wire or carbon fiber in the major axis direction of a hard needle-like member.
- 前記通電体は、ダイオードあるいはトランジスタであり、ダイオードまたはトランジスタの2端子を前記植物生体に差し込むものであることを特徴とした請求項1又は2のニードル農法。 The needle farming method according to claim 1 or 2, wherein the energizing body is a diode or a transistor, and two terminals of the diode or the transistor are inserted into the plant body.
- 前記トランジスタは、フォトトランジスタであり、該トランジスタの2端子を前記植物生体に差し込むものであることを特徴とした請求項7のニードル農法。 The needle farming method according to claim 7, wherein the transistor is a phototransistor, and two terminals of the transistor are inserted into the plant body.
- 前記ダイオードは、フォトダイオードもしくは発光ダイオードであり、該ダイオードの2端子を前記植物生体に差し込むものであることを特徴とした請求項7のニードル農法。 The needle farming method according to claim 7, wherein the diode is a photodiode or a light emitting diode, and two terminals of the diode are inserted into the plant body.
- 請求項1又は2に記載のニードル農法において、請求項5又は6に記載の通電体を、植物生体の外部より反対側の外部まで略直角に貫通させ、前記通電体の両端に、1.5~100Vの電圧を印加させたこと。 In the needle farming method according to claim 1 or 2, the current-carrying body according to claim 5 or 6 is penetrated at a substantially right angle from the outside of the plant body to the outside of the opposite side, and at both ends of the current-carrying body, 1.5. A voltage of ˜100V was applied.
- 請求項1又は2に記載のニードル農法において、請求項5又は6に記載の2本の通電体を、植物生体の茎の周囲より略直角に相対向する方向から差し込み、2本の通電体の間に、1.5~100Vの電圧を印加させたこと。 In the needle farming method according to claim 1 or 2, the two current-carrying bodies according to claim 5 or 6 are inserted from opposite directions substantially perpendicular to the periphery of the stem of the plant body, and the two current-carrying bodies are connected. In the meantime, a voltage of 1.5 to 100 V was applied.
- 請求項1又は2に記載のニードル農法において、請求項5又は6に記載の2本の通電体を、植物生体の茎の周囲より略直角に相対向する方向から差し込み、2本の通電体に、フォトトランジスタまたは太陽光発電用トランジスタの2端子を接合させたこと。 In the needle farming method according to claim 1 or 2, the two current-carrying bodies according to claim 5 or 6 are inserted from opposite directions at a substantially right angle from the periphery of the stem of the plant body, and the two current-carrying bodies are inserted. The two terminals of the phototransistor or the photovoltaic power generation transistor are joined.
- 請求項1又は2に記載のニードル農法において、請求項5に記載の通電体の軸方向に沿って溝が切られていること。 In the needle farming method according to claim 1 or 2, a groove is cut along the axial direction of the electric current body according to claim 5.
- 請求項1又は2に記載のニードル農法に用いられる通電体であって、通電性針、通電性ピン、通電性ネジ、通電性釘、通電性ステップルから選択されるもので、かつ、軸方向に沿って溝が切られている通電部材。
It is an electrically conductive body used for the needle farming method of Claim 1 or 2, Comprising: It selects from an electrically conductive needle, an electrically conductive pin, an electrically conductive screw, an electrically conductive nail, an electrically conductive staple, and is an axial direction. A current-carrying member having a groove cut along.
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JP2011538253A JP5131876B2 (en) | 2009-10-27 | 2010-10-27 | $ 1 farming |
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JP2019097471A (en) * | 2017-11-30 | 2019-06-24 | 日本振興株式会社 | Plant growth promotion method |
WO2023015351A1 (en) * | 2021-08-11 | 2023-02-16 | Grobud Pty Ltd | Device for promoting plant growth |
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Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPH11294416A (en) * | 1998-04-10 | 1999-10-26 | Tsutomu Kawasumi | Nail provided with linear groove in parallel or in nearly parallel with center axis of nail |
JP2009000093A (en) * | 2007-06-19 | 2009-01-08 | Otsuka Kazuo | Agricultural method using semiconductor |
JP2009207476A (en) * | 2008-03-03 | 2009-09-17 | Tomoaki Otsuka | Productive agricultural method for life prolongation force of living plant body and non-septic living body |
JP2009278963A (en) * | 2008-05-20 | 2009-12-03 | Tomoaki Otsuka | Method for functionally improving plant organism |
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AT396319B (en) * | 1984-12-04 | 1993-08-25 | Nogler & Daum Eltac | METHOD AND DEVICE FOR BUILDING UP AN ELECTRICAL EQUAL FIELD IN A PLANT |
JP2005073680A (en) * | 2003-08-29 | 2005-03-24 | Munemaru Masako | Method for fixing carbon dioxide by electricity and plant |
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Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPH11294416A (en) * | 1998-04-10 | 1999-10-26 | Tsutomu Kawasumi | Nail provided with linear groove in parallel or in nearly parallel with center axis of nail |
JP2009000093A (en) * | 2007-06-19 | 2009-01-08 | Otsuka Kazuo | Agricultural method using semiconductor |
JP2009207476A (en) * | 2008-03-03 | 2009-09-17 | Tomoaki Otsuka | Productive agricultural method for life prolongation force of living plant body and non-septic living body |
JP2009278963A (en) * | 2008-05-20 | 2009-12-03 | Tomoaki Otsuka | Method for functionally improving plant organism |
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JP2019097471A (en) * | 2017-11-30 | 2019-06-24 | 日本振興株式会社 | Plant growth promotion method |
WO2023015351A1 (en) * | 2021-08-11 | 2023-02-16 | Grobud Pty Ltd | Device for promoting plant growth |
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