JP7681820B2 - How to Live an Efficient Life - Google Patents

Description

Detailed Description of the Invention

For transporting objects, such as goods, the wheels of trains are replaced with sleds. Instead of tracks, a width is provided that is just wide enough for the sleds to pass through, and water is placed in that area, and electricity is used to cool and freeze them, reducing friction and reducing energy loss as much as possible. The wheels are used when accelerating or decelerating by contacting the gaps between the rails. These wheels can also be retracted into the car body using electricity to reduce resistance when the car gains speed. The sled slides on the frozen road surface, but has a rail structure with a protruding shape to prevent it from slipping off the rails. To reduce impacts on curves, tires can be attached to the sled to contact the side of the rails. The route can be designed to descend slightly, and acceleration is achieved by gravitational energy. The route can be designed without any elevation difference, but even if the route is designed to be an uphill route after calculating the construction costs, friction is reduced by the sled, so the energy of inertia can be used as an energy source to move objects to higher ground. Even on a slight downward slope, the resistance of the contact parts of the car body is extremely small, so the car can accelerate rapidly even with only a small amount of energy provided by the tires in contact. The same can be said for linear motor cars and other vehicles that are not in contact with the ground. Air resistance can also be prevented by creating a vacuum inside the tube or tunnel that surrounds the car. Possible methods include opening the hatch on the car when it arrives at the station to create a passageway to the outside, or installing partition hatches or doors that open and close at the top and bottom in the tunnel to partially let air in at sections such as stations so that passengers can enter and exit there. In order to quickly drain rainwater or other water that gets into the structures on the lane that are cooled and keep the ice in contact with the lane at a temperature with little resistance, a hollow hole is installed at the end of the lane, and the structure on the passage allows the rainwater to flow out. In order to maintain the temperature of the lane in a cooled and frozen state, the temperature of a tank installed about 5 meters underground can be used to circulate the water around the lane using pipes made of plastic bottles, reducing the energy required to control the temperature of the lane. Liquefied carbon dioxide can be passed through pipes near the cooling lane to freeze the water, etc., and can be cooled. A roof can be attached to the top to prevent rainwater, etc., and the structure can be made to shield the entire surroundings. When shielding, it can be covered with a transparent, light-transmitting material or strong plastic, or a structure made of connected PET bottles, etc. (or other dedicated ones) can be used to circulate water from an underground tank installed in a place where the temperature is kept at about 15 degrees throughout the year, about 5 meters underground (if it is underground in a mountain area, there is natural energy that falls due to gravity pressure), and the space through which cars pass can be made closer to 15 degrees Celsius, and by adjusting the flow rate of the liquid, the cost of air conditioning for vehicles can be reduced. When the space through which cars pass is reduced in pressure to be close to a vacuum in order to reduce air resistance, pressure-resistant reinforced plastic, glass, etc. can be installed on the outer periphery of the space through which cars pass to reinforce it. When water is circulated using a pump, liquids such as water do not suddenly boil even when exposed to sunlight from the outside, so there is no need to operate the pump frequently, and energy costs are low. When obtaining energy from solar panels, etc., solar panels are installed on the roof of this facility, or on the sides, lanes, or other open spaces. In order to cool the solar panels, water that is kept at a constant temperature in the underground tank circulating as described above is poured over the panels, or a pipe-shaped structure made of a light-transmitting material is installed nearby and water at about 15°C from the underground tank is poured there to control the temperature of the solar panels, or the solar panels are made waterproof and airtight, and the panels are attached to a bucket or the like that contains shallow water, and water at about 15°C installed about 5 meters underground is poured there and collected in the underground tank. If the position is such that natural groundwater flows naturally, it is acceptable to let the water flow freely, and the temperature of the panels is controlled. For example, a plastic bottle or the like is used, with the mouth part cut out to form a rectangular cube, and multiple pieces are glued together to construct a structure in which water from the underground tank can be poured into that part. Using a material such as a plastic bottle that transmits light but does not transmit water, a hollow structure is created that is filled with water.
. Then, in the hollow part, you can put things such as solar panels that you want to control the temperature. This is because the amount of electricity generated by solar panels installed in homes can be increased by installing similar devices. If the solar panels get too hot, the amount of electricity generated will decrease. Also, to efficiently air-condition the space, water at about 15 degrees from the underground tank is used. Since the ground temperature around the underground tank varies depending on the depth, multiple tanks can be installed at different depths and the water can be mixed. If necessary, a structure made of plastic bottles can be moved by draining the water. Since the material is light, it can be done by hand, but the ceiling can also be constructed in advance so that it can be opened and closed by motor drive. In the underground tank, a pipe about 5 cm long and wide (this is only a guideline and the scale can be changed freely) is installed, and a structure with a passageway that can flow water is installed around it, and the water from the underground tank is flowed there. A fan is attached to the end of the pipe to blow air. When air moves through the tube with the force of a fan, it exchanges heat with the surrounding water (for example, thin materials such as plastic bottles conduct heat easily), and gradually cools down in summer. If the length of the tube is increased to a certain extent, the temperature at the outlet of the tube will be closer to the temperature of the water from the underground tank. It will be cold in summer, and warm if the air is lower than about 15°C. For example, plastic bottles can be connected together to create a structure. Fans such as electric fans consume little power, so they are energy-efficient. The tube does not need to be straight, so it can be curved to increase the distance. It is also possible to pass a thinner tube through the tube so that water can circulate there as well, making it easier to exchange heat when you catch a cold. It is also possible to pass a rod of metal with high thermal conductivity between the passage through which the circulating water flows and the tube to increase the area of contact between the water at a temperature of around 15°C and the air flowing through. Fans can be installed not only at the inlet of the tube, but also at the outlet part or along the way to increase the heat exchange efficiency. This device can be installed indoors, but can also be installed in places with a constant ground temperature about 5 meters underground. Air is pumped in and out through pipes. If air is pumped into the pipe at a depth of about 5 meters underground where the ground temperature is about 15°C, in the summer, the air sucked in above ground travels underground and when it leaves the pipe outlet, its temperature is close to the ground temperature of 15°C. This is the same regardless of the season, even in winter. Water flows on all four sides or in certain parts of the pipe, but in the case of a two-tiered structure, the water is maintained by gravity in the lower part even if the ceiling is not sealed, so there are cases where the ceiling does not need to be installed and the water comes into direct contact with the air, improving heat exchange efficiency. If the ground temperature in most of the installation location around the pipe is about 15°C, the temperature of the original air will approach 15°C. Compressed air is used when using hot spring water or water artificially boiled in a boiler for air conditioning in homes and facilities. First, hot water is poured into a space made of PET bottles, etc., and in the above method, the temperature of the underground is about 15 degrees, and heat is exchanged to bring the temperature of the air, etc. closer to 15 degrees. Instead of 15 degrees, hot water is poured into the space, and in order to keep it warm when it is sent, it is placed in a pipe connected with PET bottles, etc., and sent in a compressed state (or a little air, etc., depending on the situation) in the space enclosed by it. The above-mentioned space for sending hot air, etc., can be installed underground or above ground, but if the ground is very cold, etc., considering the cost of digging underground, it is also possible to use an insulation system using water, etc., in a tank about 5 meters underground at about 15 degrees. Since the depth of underground tanks, etc. varies depending on the season according to the depth, multiple tanks can be prepared and water, etc. can be mixed. If necessary, the outer periphery of the device that sends the air, etc. made from PET bottles, can be covered with insulation material (such as styrofoam, which has an insulating effect) to increase efficiency. Cold air, etc. can also be sent. Plastic bottles etc. are linked together to create a rectangular or similar space, and then other plastic bottles etc. are linked within this space to create a structure etc. Then, as described above, liquids etc. can be poured in, and the items you want to dry or moisten are placed in the space where air was being sent above. At this time, it can be packed tightly so that the air etc. is not delayed, or there can be some gaps so that hot air etc. can be passed through. For example, when evaporating seawater to extract salt etc., a space containing seawater, a space above that through which hot air etc. can flow, a board-shaped passage (which can be slightly inclined) made from plastic bottles etc. is created above that, and a space through which water etc. can flow is created. The outer periphery is surrounded by plastic bottles etc. and the entire inside is filled with water etc.
The body can also be pressurized with a compressor. The evaporation of seawater is accelerated by using the power of sunlight or by flowing warm water, and further accelerated by sending in warm air. When the humidity becomes high, the inside pressurized by the compressor is returned to normal pressure and cold water from an underground tank is flowed through the pipes. When the humidity drops and the temperature nearby is cooled, water droplets from the air flow through the installed plate and move to the lowest position. This structure can be used to speed up the evaporation of seawater. The outer periphery constructed from PET bottles, etc., can be covered with transparent film or plastic as necessary to withstand pressure. When the air inside the device is released to the outside, filters to prevent salt damage can be installed near the outside air intake and exhaust fans. Salt damage is caused by fine particles generated when waves break and are blown up by the wind, so this device does not generate fine particles in the first place, so it is only installed just in case. Hatches are installed in places where ventilation is possible so that they can withstand the pressure inside. By making this device out of transparent materials such as plastic bottles, the power of sunlight can be transmitted efficiently. By laying a black material (such as a black sheet) on the bottom of the device, the energy of sunlight can be used even more efficiently. This device can be installed in a space that requires sunlight, such as a solar panel, to obtain salt while preventing the temperature of the solar panel from rising. The angle of the device can be adjusted by making a base out of transparent materials such as plastic bottles for the lower part depending on the installation angle of the solar panel. Water can also be used to clean up garbage on the top of such structures. If a filter that collects garbage when it reaches a certain point along with the water is installed, the effort of cleaning can be reduced. Water can also be circulated or temporarily stored by using the earth's temperature about 5 meters underground through a thin pipe near an object such as a solar panel, where the efficiency increases if the temperature is close to a certain level. In addition, after leaving the solar panels and other devices in this state (including the equipment to be sealed if necessary), in order to eliminate the influence of outside air and control the temperature, water using the earth temperature from 5 meters underground can be poured into a structure made of materials such as connected PET bottles, etc., and the structure can be installed in a structure that can control the temperature inside the structure, etc., to prevent the solar panels from becoming excessively hot. Water can be circulated or stopped in the structure made of connected PET bottles, etc., and the flow rate of water can be changed by adjusting the pump. The water that passes through the PET bottles returns to the underground tank and the temperature is controlled by the earth temperature. Multiple underground tanks may be installed depending on the depth. In order to control the temperature of the solar panels, etc., the circulating water can be passed through finer pipes, or such pipes may be installed in advance on the solar panels and other devices. Water from the underground tank can be poured into thin pipes made of light-transmitting materials and placed around the solar panels to use for temperature control. The pipes, solar panels, etc. are waterproofed to prevent water from entering the electrical machinery. Instead of plastic bottles, it is also possible to use thinner materials made specifically for this purpose, so that water can flow through them. For example, a thin wall of water about 2 cm thick can be used around the periphery of solar panels to control the temperature of the solar panels. When the water in an underground tank is raised to a certain height using a pump, gravity will allow it to flow around the solar panels through pipes and return to the underground tank. Water can also be sprayed on the solar panels to lower the temperature, and the water from the underground tank can be collected and circulated. A space can be created by connecting plastic bottles (it doesn't have to be plastic bottles, it can be made of special materials) and, for example, the plastic bottles can be lined up in a row in an area of 20 meters long and 10 meters wide, and the ceiling can be lined up in the same way, and the empty space can be filled with soil, etc., to create a rice field. In this way, fertilizer can be reused without escaping into the ground. If water is sprinkled on top of the soil, it will seep through the soil and reach the bottom plastic bottle, so make a number of holes in that area so that the fertilizer will seep into the inside of the plastic bottle, which will then be pumped out from the very end of the connected plastic bottles and stored in an underground tank, where it can be reused or processed to make fertilizer. The bottom plastic bottles can be stacked together, or filled with water at first to increase their strength, and the water in the plastic bottles that hold the fertilizer at the bottom can be drained to some extent after adding soil.
It is also possible. Considering the impact on the ecosystem, water, oxygen, etc. can be circulated in the bottom part of the structure made of PET bottles, etc. (if the floor surface made of the bottom PET bottles is three layers of PET bottles, the bottom PET bottle will be the part of the structure) and water, oxygen, etc. can be permeated into the soil by making holes in the bottom of the structure of PET bottles, etc. that pass through there. It is also possible to configure a structure of other PET bottles, etc. by dividing it into multiple layers, such as a function to pour fertilizer into the space constructed with PET bottles and collect it, or a layer that allows water, oxygen, etc. to permeate underground. If the top is covered with a similar structure to create a sealed state, fertilizer, pesticides, etc. will not scatter to the outside. Costs can also be reduced by reusing fertilizer, etc. When taking in outside air, a door can be attached to the top, etc., and opened, or a fan can be used to let in air, and a door for humans to enter can also be made. Such a shield can also prevent fertilizer used in agriculture, etc. from spreading outside. For example, if a stream around a house is made of concrete, there may be cases where there is little or no water flowing during the dry season. If a structure like the one above made from plastic bottles is buried underground in such a place and water can flow between them, the ground can be used effectively. In cases where river water is managed by the national government or municipalities, concrete gutters are often built, but if water hardly flows through them, the aboveground space is wasted. Also, if the boundary line of the land is a river, the river is actually narrow and only a lot of water flows through it for a short time, but the land is occupied all year round, which may lead to a situation of unjust occupation of the landowner. In addition, it is unreasonable to design gutters to be too wide or shallow when water hardly flows through them under normal circumstances. When making a gutter with a width of 1.5 meters and a depth of 50 cm, for example, if the width is 50 cm and the depth is 1.5 meters, one meter of the aboveground area can be effectively used, and the landowner of the land next to the registered river can use the land that is originally owned by the original landowner. The river does not exist as a land use in the registered land area, but the administrator is set, so there are many cases where it is not necessary to pass through the current area. If a gutter with a width of 1.5 meters is made for a river that is normally only about 10 cm wide, the landowner can notice the problem and use this underground water conveyance system to hide the original land use right. In the above-mentioned space constructed using plastic bottles, etc., a tunnel-like space is created inside that is just wide enough for a person to pass through, and a cart-like object is pulled into it using rails or tires. In hydroponics, the solution can be poured inside the space, and if you are growing plants, you can move a bucket that can hold water of a size prepared according to the growth of the roots on a cart into the space. In the case of hydroponically cultivating plants, the upper part of the plant from the roots can be moved by an upper cart, etc., so less pulling force is required. Similarly, a space for cars, etc. can be created using plastic bottles, etc., and the temperature of the internal space can be controlled using circulating water, etc., and cars can be parked and rested inside. On top of that, a structure made of plastic bottles for growing crops can be placed on top of it and crops can be grown. In addition, such a structure made of plastic bottles can be created and a shield can be set up from the outside, and a bed for humans to sleep inside can be placed inside. For elderly people, a device that can shower on the spot can be installed, and a toilet can be built in the shielded space. Water can be poured into the shielded interior periodically to clean it, and harmful substances contained in the air can be removed daily through an air filter. If installed in a hospital, etc., the airspace inside the hospital can be cleaned from ammonia, etc. It is particularly effective when many people who cannot move due to their health condition are gathered together and cannot walk by themselves to take a shower, and medical personnel can pass through the shielded space and come into contact with hospitalized patients. If you add shower equipment to a space shielded with plastic bottles, you can take a shower there, clean the space, and save the trouble of having to go to the bathroom. You can also collect bedding and replace it with new ones during showers. In short, you can avoid situations where the ammonia concentration is likely to rise by shielding that area with plastic bottles, just like the inside of a spaceship. You can also attach fitness equipment to this device, or attach a body washing device for which I have applied for a patent.
It is also possible to attach wheels to this device so that it can be moved. A space made of PET bottles or the like can be used to connect the operating space and the sleeping space, etc., in a shielded form from the outside. Since ammonia is a substance that causes such a strong odor even in small amounts, its impact on the ecology should be considered to be enormous, and it is socially important to take this into consideration. Coffee grounds or the like can be used as a filter to remove ammonia from the inside of the space. When raising fish, the space is made into a loop structure so that the fish do not accelerate in a direction close to vertical and collide with the walls of the space containing water, etc. As shown above, a space is made using PET bottles or the like and water is put in. The top can also be made into a lid using materials such as PET bottles. Then, a pump is used to suck out the water, etc. inside, and it is pressured to spray it out, or compressed air is sent in one direction to give the water a certain rotation. The width of the loop structure where the fish are swimming is about 50 to 100 centimeters (this is just a guideline). The water flow can also be stopped. A buoyant object with bait (which can float or move the bottom by buoyancy) is rotated like a clock hand, and its movement is controlled by the behavior of the fish chasing it. The water flow can be made clockwise or counterclockwise, and the direction of the bait can be freely changed. If the water flow and the bait flow are made the same and the bait moves a little faster, the fish can eat the bait with a short movement, or if the water flow is slowed down and the bait does not move, or if the bait moves slightly in the opposite direction to the water flow, or if the bait is put in and taken out of the water, the fish will concentrate on it and stay in the same place for a long time. The above method is especially applicable to fish that cannot breathe without moving. It can also be used to control the movement of the fish together with the water flow and bait by stretching a net over the area where the fish are located in a place with water. If you attach food to a desired location in the space where the fish are kept and move it using a power source (such as pulling the food along a rail attached to the top or bottom of the tank with a power source or attaching the food to a belt that is powered), you can make it move in a circular motion or in a straight line depending on the shape of the tank, etc. Also, by using automatically moving walls in the space where the fish are kept, you can move the fish from one circular loop tank to another tank space. Then, in order to return the fishes from that space to the circular loop tank, the above-mentioned door is installed, and the water flow is introduced from the circular loop into an isolated space with no water flow, and the pressure is used to return the water to the circular loop tank from another outlet, or the wall around the tank with no water flow is made higher than that of the circular loop, and water is pumped there so that the fishes can rise to a slightly higher place, and the food is automatically moved to guide the fishes, and the water is made to flow by gravity through a waterway designed to flow the water through the door of the tank toward the circular loop, so that the fishes that were in a specific location ride the water flow and move toward the circular loop. Usually, electric compressors are used to compress air industrially, but the energy of hydraulic gears is used to power the compressor, or the rotational energy of a windmill is transmitted through gears to power the compressor. Then, a tank that stores compressed air is installed in a place with a constant ground temperature about 5 meters underground, or the compressed air is blown into water in a tank installed 5 meters underground, etc., to bring the temperature close to 15°C. Natural energy such as hydraulic power can be used to power an air compressor, and stored in a tank installed underground, etc., so that it can be taken out whenever desired like a battery and used to move gears. When compressing air with a compressor, it can be cooled in an underground tank first, then compressed to adjust humidity, or the air can be stored underground to lower humidity. Tanks containing compressed air can also be placed underground to lower the temperature. Even large tanks can be installed underground, so there is no problem with the installation location. Using the above mechanism, compressed air can be adjusted in temperature and humidity, and then sent from the facility to general households through underground pipes, etc., for high efficiency. Instead of storing electricity, it is stored as compressed air (which can be in a gaseous or dry ice-like state). Waterwheel-like devices can also be installed next to rivers. If the ocean waves are in a ria coast, tsunamis will surge up to high places, so such structures can be artificially created and seawater can be brought up to 10 meters or higher from the coastline by the force of the ocean waves. This potential energy is then stored and used to generate electricity by turning hydroelectric turbines that use gravity, to power compressors that compress air, and for various other purposes.
By using the energy of ocean waves to obtain this semi-permanently, it will be useful for human life. Using this method, compressed air can be stored in a cylinder or the like and the cylinder can be moved to a location 20 meters underground, or the cylinder can be fixed in place with a diameter of 20 meters. Then, prepare a water tank filled with water or the like installed underground. If a rotating wheel or the like is installed in it and compressed air is released from below, the wheel will rotate due to the energy generated when it floats up. The deeper the water tank, the more wheels or the like can be installed, and buoyancy will provide the energy to rotate the water wheel and wheel. The rotational energy of the water wheel and wheel can be used to operate a compressor to create compressed air or to operate a generator, which is very efficient. Compressed air (gas), dry ice, and gas (Oomasa gas, HHO, GAS, etc.) are placed at a deep point where water pressure is applied in a vertical tank filled with liquid water, and heat is added from the chemical reaction of electricity or chemicals to ignite the gas (a mixture of hydrogen and oxygen is also acceptable). The heat causes the dry ice to expand, and the compressed air also generates upward kinetic energy against the water pressure (gravity), which is used to turn a water wheel, etc. This energy is recovered to run a generator. In order to increase the efficiency of the rotation of the water wheel, etc., the water wheel's blades are made movable and can be opened and closed. In this way, it is possible to prevent the rotation speed from decreasing as much as possible by opening when pushed by the gas and receiving the kinetic energy, and the water wheel's blades hitting the liquid and creating resistance. The blades open and close, but do not close completely, but open slightly, or even if they are completely closed, a buoyant object is attached to part of the blade, and when it is in a certain direction, it opens slightly due to buoyancy. The water flow or air flow can be controlled by putting air or the like into the tank to push it apart, or by attaching a plate or the like to a specific part of the tank so that the air in the tank's waterwheel blades can easily gather. If a waterwheel of this shape is installed in a tunnel or the like where there is no energy for gas such as air to rise and water pressure is applied, the blades will open where they are pushed by the water flow and close when the pressure of the water flow weakens. In hydroelectric power generation at large dams, there are some with a head of 100 meters and hundreds of meters of pipes, but if the propeller for hydroelectric power generation is only attached to the downstream part, the energy of the water flow cannot be fully recovered to turn the turbine of the generator, and losses will occur, so the head is about 10 meters and the energy is dispersed in a thinner pipe-like tunnel or tube, or a waterwheel or propeller for hydroelectric power generation is installed in the section where there was only water flow until now. In this way, the potential energy of the water flow can be efficiently recovered. Also, when compressed air is ejected from deep places where water pressure is high, and a water wheel or the like is turned by the force of the air rising upwards, if the tank is designed in such a way that compressed gas is ejected just around 1 o'clock when the water wheel or the like is rotating clockwise, the deceleration of the propeller, water wheel, etc. due to water pressure can be suppressed. Compressed gas is also ejected from the 6 o'clock direction, etc., so the clockwise rotation force continues at all times, and the energy of the compressed air, gas, etc., and the force of buoyancy due to density differences, etc. are converted into the rotational energy of the water wheel, etc. When the shaft of a waterwheel or the like is hollowed out and compressed gas is injected into it, a catch or something is placed at the 1 o'clock or 6 o'clock position, and the hole in the shaft is caught by it, opening the door and gas spouting out. When the door reaches a position where it is not caught, it closes with the force of a spring or something, or the gas is passed through the hollow part of the shaft and a metal cap is placed over it, and when a specific part of the cap is open, gas can be spouted out when the gas outlet of the rotating shaft reaches a specific position, or the compressed gas spout is linked to the position of the waterwheel, and a valve is controlled so that compressed gas comes out only when it reaches a specific position. The shaft part that transmits the energy of the waterwheel or the like can be extended horizontally to increase airtightness so that water does not come out of the water tank or tank, and passed to a part of the tank where there is no water, or once the direction is changed using gears or something inside the tank, the rotation is transmitted to the shaft that extends upward, and when it reaches a height where it can come into contact with the outside air at the top of the tank, the energy can be transmitted to gears or something again to become a power source, etc. Waterwheels and the like can be installed by connecting several of them vertically. There are various ways to think about this, such as extending the tanks deep underground or raising them above ground. They are connected by belts or something to transmit the rising energy of air in water, or the buoyancy, to the power, and are supported in some way (the angle can change depending on the resistance of the buoyancy, like a bicycle chain).
It is also possible to use a structure with a plate or the like that can be moved (although the angle of the plate does not necessarily have to change depending on resistance, etc., due to installation costs). In addition, the energy obtained by buoyancy in this way can be connected with a shaft and used as upward moving energy to lift water, etc., and can also be used for pumping. These can be divided into sections of 10 meters or so, and the water pressure can be adjusted and used in multiple vertical connections. The air, etc. can be reused by using a structure that flows from the lower structure to the upper structure again through pipes, etc., and the upward energy of the injected air, etc. can be efficiently used. The energy associated with the upward movement of the air, etc. in each structure can be converted into driving energy, etc., through shafts, etc. Water, etc. can be pumped up because the air, etc. of this device rises and is in a place where it comes into contact with the water, etc. waiting on the ground, etc. By using a similar structure like a bicycle chain, etc., it is possible to transport water, etc. upward along its rotation. By stacking such devices vertically in multiple layers, the upward movement energy of the air, etc. (carbon dioxide, etc. can also be used) can be efficiently used and converted into energy, and the water pressure can also be controlled. The air, etc. is not released to the outside, but is collected in a tank, etc. and reused. Once compressed air is put in, it can be operated semi-permanently based on the laws of gravity by preventing leakage to the outside. Pressure-sensing sensors can be installed on the paths connecting compressed air, and valves that open and close in conjunction with the sensors can be installed to optimally control the pressure of each part through which the air flows. The valves that open and close can be electronically controlled or analog, such as springs that open and close according to pressure. The devices can be connected horizontally instead of vertically, and can be made small in size, and the extracted power can be used as various forms of energy sources. Of course, such devices can be installed on ships to use as propulsion. In order to use energy efficiently, water can be moved to a high position, such as 60 meters above ground, using a pump, elevator, vehicle, or other method that uses buoyancy as mentioned above, and then the pipes are turned downward to drop the water, and the kinetic energy is used below to power a propeller for generating electricity. Of course, this energy can be used in various ways as power. If such a device is installed on a ship, it can generate electricity or directly reduce propulsion energy. Even without using pipes, a certain amount falls to a limited point. Since the kinetic energy increases in proportion to the square of the moving speed of the object, energy can be obtained efficiently. At a height of about 60m, the kinetic energy is 625 times that of a speed of 1m/s. Even at 40L per second, considerable power can be generated. Energy is efficiently increased by water falling vertically. The energy of the movement of the material is efficiently increased and used as power for generators, etc. (For example, to turn turbines for hydroelectric power generation.) When installing, for example, natural topography such as mountains and valleys can be used to reduce the cost of building large-scale facilities from scratch by using spring water if there is spring water. Existing buildings can be used or parts of the edges can be modified. When a certain amount of spring water is bubbling up near the top of a mountain, the water can be pulled to a specific point using pipes while maintaining the height. If the amount of water is small, it can be pumped up using power, etc., and transported from below for reuse. Even if the difference between the top of a mountain and the nearby lowlands is 50 meters, the original height of the mountain means that only that part needs to be kept at about 50 meters, so scaffolding may be required. Mountains are usually uninhabited, so it is easy to install pipes in those parts. Scaffolding made of wood or concrete can be used to create platforms to support pipes. Hydroelectric power generation at dams and other facilities involves storing water that has flowed down from the surrounding mountains and then using the height of the waterway further down to obtain energy, but it is also possible to obtain high energy while keeping construction costs low by making use of the topography of the mountain itself. By digging down the lowlands and placing generators underground, noise and other issues can be avoided and the difference in height can be made wider. When water is dropped downward through a pipe or other device to generate electricity, a pipe that can send compressed air or the like can be connected to the upper part of the pipe to make the water fall downward more quickly, or a structure made of multiple thin pipes bundled together instead of a single pipe can be used, and the inner pipe of the bundle can have several holes for ventilation, through which compressed air can be sent from the higher part of the pipe to make the water fall smoothly through the pipe. If there is no spring water, a certain amount of water can be brought in or rainwater can be collected and used.
Vehicles can be moved efficiently using structures that slide on the ice that has been laid down, and if rails are constructed to accelerate the vehicle upwards using gravity energy or an engine to some extent, the energy required to move the water to a higher position can be obtained by the acceleration caused by gravity, so the energy cost required for propulsion can be reduced. Of course, such a device can also be installed on ships and used as propulsion. The temperature around 5 meters underground in the Japanese mainland is kept at about 15 degrees throughout the year, and by using this natural law to build a tube-shaped tunnel there, the energy required for cooling can be saved. Alternatively, when this structure is grounded on the ground and cooled, the outer periphery of the tube can be covered with liquid water, and if the outer periphery of the tube is made of plastic, glass, or other material that transmits light, the scenery can be seen from inside the vehicle. Water can also be filled into a similar tunnel, and ships can be driven with the inside sealed, and the energy efficiency during movement can be increased by creating a vacuum inside the tunnel (anything that can run inside a tunnel can be used). Even if it is not a large vehicle like a train, a similar structure can be used in cars, etc. to reduce energy costs. It increases the reliability of automatic driving of cars. A car is connected to a cart installed on a similar platform, and the weight of the car is supported mainly by a sled, reducing rolling resistance. There are various methods, such as incorporating a motor to contact the road surface and transmit power to the cart, connecting the power of the car's engine and motor from the car's tires, engine, motor, etc. to the power section of the cart while the car is on the cart, or equipping the cart with a device to transmit the rotational force of the car's wheels to the road surface as necessary. In addition, even if an existing vehicle is not used, if it is a four-wheeled vehicle, two more wheels are attached to the center of the vehicle body, and this part does not come into contact with the ground during normal driving, but if the angle is changed by hydraulic pressure, etc., it can be structured so that it comes into contact with the ground, and the four wheels are used to ride on the cart, and the remaining two wheels (rubber, iron, etc. wheels) are used hydraulic pressure to make them come into contact with the upper part of the cooling rail as needed, or the cart can be given the function of a hydraulic jack, and after the car rides on the cart, the car can be raised and lowered by hydraulic pressure, so that the height of the car's tires can be changed to prevent it from coming into contact with the ground. This cart can be equipped with a motor to obtain driving force during driving, or part of the cart can be powered to pull or push, and connected to other carts like a train, or powered carts can be appropriately arranged to reduce installation costs. The movement of the cart (unit) can be monitored by sensors, and cameras can be installed around the cooling lane, so that the cart can be automatically controlled without human intervention. Solar panels or the like can be installed near the space where such cooling lanes are installed, and electricity from the panels can be led from the metal parts of the lanes to the motors of the carts, or non-contact power transmission can be used so that the lanes and the electric receiving parts of the carts do not have to come into direct contact with each other. There are several methods, such as attaching a device to the side of the tires of a car or the like to connect the tires (which can be made of iron) so that their rotation does not come into contact with the road surface or the ice-free upper part of the cooling rail installed on the carts, and converting the energy of the car's engine, motor, etc. into running energy, or attaching a roller part device to the cart that rotates in response to the rotation of the tires by rotating the engine, etc. on the spot without changing the position of the car passing through during inspection, and connecting it to the wheels with a mechanism that converts the rotational energy of the roller part so that the wheels of the cart do not come into contact with the road surface. In order to prevent the road surface part that transmits the running energy from freezing, water stored 5 meters underground at about 15 degrees due to geothermal heat is led to the vicinity of the road surface through a pipe to prevent this, and the water is collected by a motor pump and collected in a tank so that it can be circulated. For emergency stops, posts or the like are placed at the rear of the carriage, and if necessary, these can be lowered onto the road surface to quickly stop the train. Even when using technology such as linear motor cars to obtain energy in the direction of travel, if part of the magnetic field of the linear motor car's tracks is cooled and covered with ice, and a sled or other device is attached to reduce resistance during movement, the vertical levitation force produced by electricity can be saved, and most of the electrical energy can be concentrated in the energy in the direction of travel, making it more efficient. The levitation energy and the energy accelerating in the direction of travel when a linear motor car is running can be achieved by adjusting the direction of the applied magnetic energy.
In order to save electric energy, etc., the levitation energy is kept low, etc., and the balance between power consumption during movement and speed is adjusted to be maximized. Even if the vehicle does not actually float, it can run with reduced resistance because of the sled. For ride comfort, etc., a small amount of water can be poured on the frozen person. A sled and the above-mentioned powered wheels can be attached to the linear motor car. The inside of the tunnel can be made close to a vacuum state to eliminate loss due to wind and reduce noise, etc. The magnetic energy transmission part of the linear motor car and the sled device can be installed separately. Wings can be attached to the top of the vehicle to obtain lift and control air resistance, and friction with the frozen lane can be further reduced or adjusted to reduce the frictional force acting on the sled of the vehicle against the cooling lane, or conversely, the vehicle can be pushed down toward the cooling lane. In order to prevent the sled from derailing from the cooling lane, the sled can be sandwiched between the cooling lane and the sled, and the cooling lane can be shaped like a zipper so that the sled can be fitted into it. The direction of the wings can be changed and the balance of lift can be adjusted on the left and right to make it easier to turn when cornering. The flaps can also be adjusted to increase air resistance when decelerating. In the event of an emergency stop, the parachute can be set to extend from the vehicle. To prevent the parachute from getting tangled, the device with the parachute attached can be detached from the rear of the vehicle and moved along the lane, allowing the vehicle to stop safely while still receiving the benefits of the parachute. The parachute device is connected to a device that moves on the cooling lane by wires, and the device and the vehicle are also connected by wires. There are various possible sources of energy for the movement of such vehicles, such as wheel drive, jet engines, or propellers attached to the sides or rear of the vehicle. After accelerating considerably, the vehicle can fly into the sky in the direction of travel and glide from there, or it can be moved at high speed using a jet engine, rocket, etc. attached to the vehicle as power, or lift from the wings, or it can be used to launch satellites into orbit while saving fuel. One method is to accelerate the satellite sufficiently on the cooling rail and launch it upwards, then separate only the satellite (by using the pressure of compressed gas, etc.) and further accelerate it using a jet engine, etc. It is also possible to accelerate it on the cooling rail from the beginning using a jet engine, rocket, etc. To cool the part where the sled is in contact, it is possible to make a long and thin heat absorbing plate from a freezer and install it there, or to use a dedicated heat absorbing device, or to use efficient temperature management using a large compressor and water at a constant temperature underground. It is also possible to use the exhaust heat of the compressor to run a Stirling engine, etc. as a secondary use. Water drawn from a compressor 5 meters underground can be circulated around the compressor using pipes, etc., and heat exchange can be performed in necessary places to take advantage of the exhaust heat. To cool the water in the cooling lane, etc., a pipe is installed nearby and gas without humidity is put into it. Then, cold air such as dry ice can be circulated using a fan, or a tank filled with carbon dioxide at a low pressure can be used to suck it in at the outlet of the pipe. Once the carbon dioxide has been collected at one end, another pipe can be used to flow cooling gas in the opposite direction in the same way, saving storage space for carbon dioxide, etc. Fans can also be installed midway through the pipes as necessary. Carbon dioxide collected through the pipes can be made into dry ice, etc., and reused. Carbon dioxide gas can also be obtained by applying heat to dry ice in a vacuum, and then introduced into pipes, etc. When sending it into a pipe, the speed can be increased by compressing it, etc.
Even in the current roads, water in tanks installed 5 meters underground under roads and passages is circulated 10 cm (approximately) below the asphalt of the road using pipes to prevent freezing and excessive heat from the road surface. Circulating water can also be made to flow around the sled using pipes to increase cooling efficiency in summer. Using plastic bottles, etc., a space the size of a futon (the size can be changed to be larger or smaller) is made, and the space is kept cool in summer and not freezing in winter. Water from a tank installed about 5 meters underground is put into the plastic bottles through pipes and the plastic bottles are connected so that the water circulates and returns to the tank. Water can be pumped using motors, installed underground in high mountains, or sent to each home using large underground tanks linked to large facilities such as water purification plants, with a temperature close to 15°C even in summer. Water can be pumped using water pressure alone. Cooling rail (lane)
The cost of cooling towers can be reduced by placing a sealed cover on the top of the rails, lanes, etc. and circulating water at about 15 degrees from underground tanks through it. The upper covers of cooling rails, lanes, etc. are closed electrically especially in summer to minimize heat exchange, but when vehicles pass through, they can be detected by a sensor and opened and closed automatically by a motor.
Add functions to cooking utensils to prevent the white part from burning when frying eggs, etc. Provide a space for water on the top of the lid, etc., and allow it to drain moderately through holes around the lid. Make the size of the hole adjustable with a screw or other device. Make ridges in the bottom of the frying pan so that the water that falls to the bottom can flow through them. The yolk is in the middle, and 12 ridges like the hands of a clock are made to make the slope deeper in the middle, making it easier to move to the center. When you want the flame of the stove to go toward the white part and concentrate the heat on the yolk, etc., prepare a special shape for the gas outlet of the stove so that the most gas comes out in the center and very little or no gas comes out around the edges. Switch the gas pipe with a lever or other device to divide the heat into normal, most of the heat goes to the center, or only the center. When cutting wood, etc., cut at high speed using HHO gas or Oomasa gas to increase efficiency. Apply gas at high speed to localized areas. After cutting, pour water nearby to cool it down completely. A nozzle that sprays water can be installed at the gas outlet to prevent the water from spreading to the surrounding area more than necessary. The nozzle can be made long and thin to only spray water on a small area. To increase efficiency, multiple gas jets can be used to cut in a short time. It can be made circular and set around a tree, or it can be shaped like a crescent moon to cut about 70% of the tree. In order to avoid the need for a human to support the chainsaw, a strong rod-shaped object that can be fixed to the tree can be placed near the handle of the chainsaw, and the tree can be fixed to it using bolts. Then, hydraulic pressure can be applied between the part that supports the rotating blade of the chainsaw and the rod that fixes the tree to the chainsaw body, so that the chainsaw blade can be pressed in a certain direction. The part that supports the hydraulic pressure can be changed as needed to increase efficiency. To make an emergency stop of a train, a pipe is installed under the train track and oil (or clay or gas) is poured into it. A hole is then drilled in the top of the pipe and a stake is dropped from the train to hook it. The place where the stake falls can be contacted with a round plate made close to the pipe to prevent pressure from escaping, like an air gun, and the pressure inside the pipe is increased, slowing the train. If multiple pipes are installed and there are multiple stakes on the train, one stake (a rod-shaped object used to hook the vehicle to the outside) can be hooked first, then the second and third, and so on, to adjust the braking force applied to the train. If holes are drilled in various places on the pipe to release pressure, when a certain pressure is reached, a plug is removed, preventing the pipe from breaking due to sudden pressure. To reduce the air resistance of the train, the train doors are made to lift up, and passengers can get on and off through them to lower the train height. When the pressure in a pipe containing oil or other liquid or gas used for braking reaches a certain level, it is released (or the plug is removed mechanically (a device that can remotely open and close a door installed inside the pipe to allow the passage of liquid or gas) or a hole is made in another pipe, and a pipe that can pass liquid or gas is connected, and a pressure reducing plug or another dedicated hole is made in the adjacent section and connected to it, so that when pressure is applied, the liquid or gas will move to that section, thereby increasing the braking force. Normally, there is a moderate amount of liquid or gas in the pipes, which prevents sudden shock to the vehicles, etc. Also, if necessary, a dedicated device can be prepared (such as a hydraulic pump) to send liquid or gas into the pipes, so that oil, liquid, solids, etc. can be sent quickly to the required section when needed. When connecting a vehicle to a pile or some other object (hooking structure) to soften the impact on the vehicle, etc., a shock absorber such as a spring or hydraulic shock absorber can be installed between the vehicle, etc. and the pile (hooking structure). When freezing liquid such as water in the cooling lane, a gas such as carbon dioxide can be filled into the pipes, etc., and compressed into it.
Or it can be compressed and sent in, like vaporized dry ice blown in air. It is then collected at the end of the pipe, turned into dry ice again, and returned to the original direction using another pipe for reuse. Materials such as plastic bottles can be used to protect the ground surrounding cedar seedlings, etc., planted in mountains, etc., from plants that become obstacles when the cedars grow. In this case, the plastic bottles can be processed into a board-like shape and fixed with stakes (wood, etc.), or a suitable number of holes can be drilled to allow water to pass through the soil. By using materials like plastic bottles that change naturally, it is possible to save time later. It is not necessary to use plastic bottles, but if there is something that can be placed around the surrounding plants to prevent them from growing and becoming an obstacle to the growth of cedar seedlings, etc., a dedicated vinyl sheet can be used, but the cost may differ. When fixing a plastic bottle or other plate-shaped object, it is possible to fix it as close to the ground as possible, but it is also possible to leave a space between the object and the ground by slightly expanding the surrounding plants and adjusting the amount of space around the plastic bottle or other plate-shaped object. For example, when carrying wood (not necessarily wood, but special materials can be used) from a forest that slopes downward from a forest road, plastic bottles can be connected to build a pipe-like structure that can withstand water pressure and does not leak, and wood can be placed inside it. Wood can be placed in a net and connected, or a large net that runs from the entrance to the end of the pipe can be passed through in advance with holes only in the necessary parts, and the net can be tied off after the wood is placed inside. Water can then be poured into the pipe, and the buoyancy can be used to pull the wood from the top with a winch or human power. After carrying up the lumber etc., the water can be pumped back into a tank and used again to give the lumber etc. buoyancy. Spring water in mountainous areas can be used, or rainwater can be stored in a tank. Of course, this pipe structure can also be used to move lumber etc. down the mountain, using buoyancy etc. to move lumber etc. with less energy. Buoyancy can be used when pulling on flat ground, and by connecting pipes on a slope from the top of the mountain, water pressure from above can be used to move lumber etc. more efficiently. Water can be stored in a tank etc. (wood etc. can be stored along with water etc.; it is like a waiting area for transportation using this pipe etc.) and reused. Tanks etc. can also be partitioned using nets etc. to make it easier to reuse water etc.
It is made by cutting, compressing or crushing fuel such as wood or charcoal into a rolling sphere and processing it into a sphere. When processing fuel, the necessary items can be placed in a spherical mold (a hollow shape like a broken ball, and the processed items can be placed in the mold to return it to a sphere) and pressed. In order to prevent the fuel from absorbing moisture or changing its quality, holes can be made inside the fuel to allow air to pass through, or moisture absorbents, preservatives, deodorizers, etc. can be mixed in, or the outside can be coated. It can be easily moved to the combustion area by rolling it by gravity, and it is also effective as interior decoration. It is possible to use the heat from a combustion device to heat a certain space, or to create a certain space inside a structure such as a combination of PET bottles (or a special material) and send hot air into it, or to heat liquids and circulate them inside a structure made of PET bottles, or to pour them into the area where juice was originally in the PET bottle, and control the temperature of the enclosed internal space. For example, combustible materials such as wood or charcoal processed into pieces the size of golf balls could be placed in a container higher than the combustion site, and a pipe or the like could be used to connect this to the combustion site, with a device (such as a stopper that can be raised and lowered electrically) that can stop or allow anything that rolls along the way to be passed, controlling the movement of fuel to the combustion chamber. By automating the effort of adding firewood, it would also be possible to make efficient use of forest energy. If the fuel could move automatically, using gravity to roll down to a space-saving size each year, refueling would be easy and user-friendly. It could be operated with the flip of a switch like a conventional air conditioner, and refueling would not have to be done so frequently, saving effort. As the fuel rolls, it could be made into a spiral shape and pass through loop-shaped rings, etc., which would improve the efficiency of the system.
It also has a territorial element. After processing the fuel into a sphere, the surface is coated with adhesives (such as rice paste-like starch, which is natural and does not emit harmful gases when burned) or plastics (natural ingredients that do not emit harmful gases when burned, etc.) to make it easier to slip and store. For safety, stoppers are installed in the fuel supply passages to block the flow. Devices that measure the carbon monoxide concentration in the space are also installed and linked to the device so that the stoppers will automatically activate in an emergency, increasing safety. A seismometer can also be installed to automatically activate stoppers in the same way. In order to keep the fuel storage area and the paths through which the fuel rolls and other such areas airtight and to keep them from coming into contact with the outside air as much as possible, the fuel stock is airtight, and if a vent is installed, a moisture-proofing agent is installed to isolate the outside air from the fuel. The stoppers can also be designed to open when passing through, but close otherwise to prevent outside air from entering. In order to secure living space and use it more efficiently, for example, next to a cedar tree (it doesn't have to be next to a cedar tree), a space with a diameter of 4 meters that a person can enter is made of wood, concrete, etc., and the height is up to 20 meters, making something like a small tower. A space of about 2 meters in height can secure about 40 square meters. An elevator is installed at the end of the space for people to go up and down. Water with a temperature adjusted using the ground temperature about 5 meters underground is pumped or the natural elevation change is used (in mountainous areas, water naturally rises to a high position due to gravity) to flow through pipes made of plastic bottles (special materials can be used instead of plastic bottles) to keep the temperature of the living space at an appropriate level. The pipes are attached as much as possible so that the temperature outside and the temperature of the living space can be controlled efficiently. The installation of the pipes is also energy efficient because once the water is raised to the top, it flows downwards. If a room with an outer perimeter like this is made of plastic bottles, etc. is installed on the top floor, you can see the stars at night and use it as a bath for a very relaxing experience. In addition, water in a structure made of PET bottles attached to the periphery of the roof, which is prone to heat up, can be kept on the roof so that it can be heated to a certain temperature by sunlight, and it can be stored and used in showers, etc., by isolating it from the water circulation route for conventional air conditioning, etc. Since each space is divided into small sections, auxiliary air conditioning is only required for the necessary areas, which reduces costs. Each room space is perfectly decorated, and people can move there by elevator, etc. as needed, so the space is less likely to become messy. It can also be said that security is increased because the entrances are limited, and security can be further improved by connecting the entrance to the structure made of PET bottles on the tower with a tunnel made of PET bottles, etc., and installing remote monitoring cameras at the entrances and passageways. If the entrances of multiple towers are connected with such an isolated tunnel-like space (which can be above ground or underground, etc.) and the entrances have a locking function, it can also be effective in limiting intruders. In order to grow wasabi, etc., it is also possible to connect plastic bottles together to create a space inside, and use water maintained at about 15 degrees using the earth's temperature about 5 meters underground. It is also possible to cut off the tops of 2-liter plastic bottles for drinking and line up eight of them to create a space in the middle. (They are transparent, so light can pass through. Special materials can be used instead of plastic bottles.) If necessary, air intake holes and pipes for discharging water can be inserted into the space. It is also possible to run water through the space where such plants can be grown, and depending on the temperature of the water, the temperature of the liquid flowing through the surrounding plastic bottles can be heated or cooled, thereby controlling the temperature inside the space, and the temperature of the space can be adjusted by blowing heat or air conditioning into the space where such plants can be placed. It is also possible to float even smaller plastic bottles like boats using the water flowing in the space where the plants can be placed. They can be connected to ropes and pulled, or a large number of floating objects can be moved by attaching propellers for propulsion to the floating objects. It is also possible to put a hydroponic cultivation device, soil, stones, etc. into the object that can float in water, etc., so that plants can grow. In order to efficiently cultivate wasabi, etc., a small space for cultivation can be created using a plastic bottle, etc.
They can also be connected in the same manner as above. Plastic bottles or other objects can be laid on their side, with a partition inside and transparent materials such as marbles that will not deteriorate due to water being placed in the upper part to create a wasabi culture medium. The lower part is opened so that water can enter and flow easily. Marbles and other objects can be specially processed to be hollow inside. The marbles can be of any size, from large to small, so that an appropriate size can be selected depending on their position relative to the wasabi. If a plastic bottle or other object is laid on its side and likened to a boat, the top part is cut and holes are made so that the wasabi can grow. Do not make more holes than necessary, but use them to prevent pests, etc. Several such boats can be connected to each other to make a waterway made of plastic bottles or other materials so that the boat can float, and more plastic bottles can be connected around it. Spring water can flow through the connected plastic bottles by taking advantage of the difference in elevation. When harvesting or caring for the crop, the connected boats on which the wasabi is grown can be floated and pulled by the buoyancy of the water to the desired location where work can be done. Such wasabi-growing devices can be stacked vertically, aiming to increase the harvest yield. The above-mentioned salt can be extracted by drying seawater, and wood can be placed inside the boat to dry it and reduce the moisture content of the wood, thereby increasing the efficiency of using wood as fuel. To dry more efficiently, a vent can be provided in the structure constructed using the plastic bottles, and air can be blown in from there with a blower to dry it, or it can be closed and a dehumidifier installed. A rope can be attached to the drone to limit its range of movement, and rails (lanes) can be laid at the point where the drone is to fly, and identification radio waves can be transmitted and received there, allowing the drone to fly on a certain rail using the rail as a marker. This ensures the accurate flight and safety of drones in forest areas where GPS cannot reach. Radio waves emitted from the drone can be used to determine the exact positional relationship with the lane, and the drone cannot deviate from the certain lane. The reflected radio waves can be used to calculate the distance, altitude, speed, etc. from the drone's lane. When transporting trees and other items from mountainous areas, bicycles that can run completely on motor power instead of human power are used. Fully electric bicycles are fitted with training wheels to prevent them from falling over. Rails are then made so that the tires can run on them. Like the drone above, the position of the bicycle can be determined using sensors, and based on that, it can be remotely operated using a computer, or it can be driven automatically. Instead of lanes, a required number of terminals that can transmit information using wireless signals, etc. are placed along the way to the destination, and based on that, the moving object can read its own position, speed, the slope of the land, etc., and use that information to operate the handlebars. It does not have to be a fully electric bicycle, but a dedicated car would be fine. A powerful vehicle such as a buggy can carry a lot of luggage. Braking can also be done automatically. On slopes, if the bicycle is motor-driven, the force to turn the motor in the direction of the burner can be applied to allow the bicycle to descend slowly. The temperature inside a residential building can be controlled by lining up such structures on the roof of a house in the same way that solar panels are cooled by connecting plastic bottles, and pouring or storing water into them. Water can be circulated by installing tanks about 5 meters underground, where the ground temperature is about 15 degrees throughout the year. Water can be stopped for a certain period of time, such as when the temperature changes on the roof. A structure made of plastic bottles (not necessarily plastic bottles) can be designed to be buried under roof tiles. Multiple underground tanks can be prepared and connected to each other to set the depth at different positions to finely adjust the temperature, and if natural cold spring water or hot spring water can be used, it can be pumped directly. In winter, snow can be prevented from accumulating on the roof. Also, by pouring water on the top of this structure, the exterior of the structure can be cleaned. In order to control the temperature in spaces where people are present, such as cars, a structure is created around which water circulates and remains, using something like connected plastic bottles, and the temperature of the space within is controlled. Water is prepared and poured into the structure made of plastic bottles, and ice made in a freezer can also be placed inside to lower the temperature even further. Inside the freezer, a long, thin tube as described above is passed through which tap water is poured and frozen. Air from inside the vehicle is drawn in and out using a fan, etc., and cold air is sent inside the vehicle. Dry ice can be placed inside the freezer, or a structure made of plastic bottles with a hollow interior that people can enter can be placed inside.
It can also be placed in places that contain water. (It is also possible to put only dry ice without water.) Freezers can be powered by batteries or solar power so that they can run even when the engine of a car is turned off. Pressure valves and fans can be installed to release carbon dioxide into the atmosphere, and freezers can be equipped with a similar mechanism to release carbon dioxide into the atmosphere. This mechanism can also be used in transport trucks to control the temperature inside vehicles and containers. Spaces where humans can live are created using materials that store carbon dioxide, such as wood. Since wood fixes carbon dioxide in the atmosphere, it can be used as a construction material without burning it. This wood can be used in places where water has accumulated, such as large dams, to fill the space like building blocks, or to create spaces inside where humans can be active. Wooden pillars can be built densely like the three great pyramids of Egypt, leaving a moderate amount of space inside. (It is possible to create a space larger than Central Park in New York. An airplane runway can also be built there.) By utilizing places such as dams in the mountains in this way, vast spaces can be obtained. To prevent wood from rotting, it is also possible to coat the dam with a water-impermeable material such as a plastic bottle between the dam and the ground. If a large dam like the Kurobe Dam were to be replaced with a space where humans could live using this technology, the number of people equivalent to that of a city could live there, and the purchase price of the wood associated with this could be made commensurate with transportation costs. The water from the dam could be put into a space created further below the structure, or into a space created at the top or around the inside of the structure, or a small dam could be created at the edge of the dam. It is also possible to use a space created using a plastic bottle or the like at the top of the structure to control the room temperature inside, and by shielding it from the outside air, it is possible to prevent the temperature of the lower part from becoming excessively hot due to solar heat, or to prevent the temperature from dropping due to cooling by the atmosphere in winter. In order to prevent the deterioration of wood, chemicals and materials for moisture prevention and corrosion can be appropriately placed. Urban functions can be concentrated in a structure 50 or 100 meters high (the size can be freely selected), a vast space can be created in a place with clean air, and carbon dioxide can be stored semi-permanently. The device I invented that generates power from water, air, etc. can continue to generate energy without emitting carbon dioxide, so if we use this method to store the carbon dioxide that humans have emitted up until now, we can develop new, clean spaces for living and working, and solve both the climate change and energy problems. It is a much stronger structure in the event of an earthquake, as it can be structured so that it is in contact with the mountainside, etc., and there is almost no risk of it collapsing. For housework, the air is controlled by pipes from the outside, so there is no risk of the air being cut off and the fire spreading. By circulating water from underground tanks in an appropriate amount of space, it can be used for air conditioning and also for fire extinguishing. In a structure where wood and other materials are combined like pyramid stones, and there is a space inside, water can be circulated from underground tanks using materials such as plastic bottles, which can be used to control the temperature inside and around the space. Of course, wood and other materials can be sawn into lumber and assembled into cubes. Steel frames can also be combined for reinforcement, and pillar adhesion techniques that do not use nails can also be used (for example, by making pillars uneven and fitting them in). The creation of a vast flat space on top of the building allows for a spacious area for sports and recreation. It is possible to store wood on the large land (no need to saw lumber) and to build a space where people can live. In places like the Antarctic or Arctic, the land is large and the climate makes it less likely for wood to decay. (You can take it with you and store it for a long time. You don't need to saw lumber, etc.)
This utilizes the fact that temperatures are maintained at about 15°C all year round at about 5 meters underground, and the fact that temperatures change depending on the depth underground. On mountain slopes and the like, a depth is determined according to the required ground temperature, such as about 5 meters underground or a little shallower, and a tank made of PET bottles or the like is filled with water in advance, and a structure is constructed for controlling the temperature of the air created using the PET bottles or the like mentioned above. Space is provided inside the PET bottles or the like through which air can pass, and by passing through this space, the air temperature can be controlled. This air is then passed through pipes made of PET bottles or the like to the PET bottles or the like installed above ground, etc.
The tank is connected to a space where plants are grown, which is made up of a structure made up of a suction port and a tank for growing plants. Outside air is taken in through a specific intake port and circulated to the underground space and the space where plants are grown. Outside air can be blocked and special gases can be circulated, or air filters can be used in the outside air intake section to purify the air. The underground tank section can be prepared at multiple locations, some higher than the structure for plant cultivation, by taking advantage of the difference in altitude of the mountain. In this way, the temperature difference with the outside air can be used to naturally create convection, reducing the cost of air circulation, and if necessary, a fan driven by a motor can be installed to flow air into the space where plants are grown. The plant cultivation space can be designed to be so narrow that it is impossible for a person to stand and pass through, making the most of the space. Pallets with plants set on them can be placed on a cart and moved in and out of the cultivation space using tires or rails. Instead of sunlight, LEDs or elements that convert heat to light (announced by Kyoto University, etc.) can be used, or sunlight can be drawn into the space for plants using mirrors or optical fibers. If the heat applied to the conversion element affects plants, etc., a pipe-like device can be set between them and water can be circulated there to cool the plant cultivation space, and since the plant cultivation space is originally constructed with plastic bottles, etc., excessive temperature fluctuations can be prevented by circulating water at a constant temperature, such as 5 meters underground. In a system that uses underground temperature, air adjusted by the underground temperature can be circulated from the underground space to the plant cultivation space, and water stored about 5 meters underground can also be circulated at about 15 degrees. The plant cultivation space can be made large enough for humans to enter, and can be used for purposes other than plant cultivation. The plant cultivation space is separated from the outside world by a structure made of plastic bottles, etc., and in order to control the temperature and humidity inside, air adjusted by the earth temperature is moved from the underground structure that uses the earth temperature to the plant cultivation space through pipes, etc., but at that time, only the air can be moved, or water can be moved along with the air and the water can be poured into the place where the plastic bottle juice is stored, which can also be used to control the temperature of the plant cultivation space. In some cases, only water can be circulated, or only air can be circulated. If the plant cultivation space is designed to be long and narrow so that humans cannot enter, it will be possible to make effective use of the space, and multiple plant cultivation spaces can be stacked on top of each other. From the plant cultivation space to the work area where humans can care for the plants, etc., a long and narrow tunnel made of similar PET bottles can be placed underground or above ground, and the plants can be set on a cart and pulled by an electric tow truck or winch on rails or something. If the work area is sealed so that the work can be done while being isolated from the outside world, it is possible to prevent the invasion of bacteria from the outside and events such as seed cross-pollination. The size of the plant cultivation space can be changed, so it can be made large enough for humans to enter and work there, and if a solar power generation system is installed in the space, the temperature of the solar panels can be controlled to generate electricity efficiently. These inventions will be useful for a society in which goods and services can be exchanged in a manner that allows communication. In order to contribute to the construction of a rational society using the invention technology as a basic security, services can be provided to each other, and in order to continue the service, the inventor will be given the management rights of the service network by contract to the person who agrees with the inventor, and the inventor will manage it.

global environment

Land-based aquaculture

Patent No. 6092454

JP2018-93852 University of Tokyo, Ground temperature data, Japan Association of Groundwater Hydrology, Kyoto University, Osaka Gas joint research. First successful conversion of thermal energy into light with wavelengths that solar cells can generate electricity efficiently. Published in Science Advances on December 24, 2016. Nano-resonators made from silicon. www.kyoto ou.ac.jp Vegetable growth conditions www.atariya.net Himawari, a lighting system that uses the sun's blessings www.himawari-net.co.jp Calorific value of fuel www.hakko.co.jp

Improving energy costs, etc.

Improving energy costs, etc.

Use a sled, etc. Create a structure to properly distribute water, etc.

Trees, etc. Vehicles etc. Water, etc. Power generation, etc. Power unit, etc.

Independent industries can be established even in depopulated areas.

Claims (1)

When considering the mechanism of movement of an object, generally known as a train, in order to move or stop such a device (a movable object) more efficiently, the structure where the wheels are usually in contact with the track is replaced with a sled. Instead of the track, a structure with a width just wide enough for the sled to pass through is constructed, and water or other substances are placed in that area to cool it down and freeze it, reducing friction, so that the sled can be placed on top of the cooling substance. A power transmission device is used to transmit the driving force to power the car body and move it efficiently. In this device, in order to make an emergency stop of a movable object, a pipe is installed under the moving track and a viscous substance such as oil is poured into it, a hole is made in the top of the pipe, and a stake or something like that is dropped from the moving object is hooked into it, and the place where the stake falls comes into contact with a plate made as close to the pipe as possible to prevent pressure from escaping, like an air gun, and the pressure inside the pipe is increased, slowing down the moving object.

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