JP7456701B1 - Offshore research laboratory - Google Patents

Abstract

[Challenge] Conventionally, seaweed that produces blue carbon has been left to grow in the natural environment and has been limited to shallow waters where sunlight is abundant. Although the growing area may have decreased, it has not increased. [Solution] A cultivation soil unit for cultivating algae is made lighter by the buoyancy of multiple sealed wooden boxes, and then suspended from multiple wooden artificial island units with four wires, and the cultivation soil unit is used to grow algae. In order to cultivate algae and improve the breed of algae that can carry out efficient photosynthesis, we also considered the distance from the sea surface that provides the best growth conditions for algae, and cultivated algae in the culture soil that has the highest nutritional value for the algae. Build an offshore research laboratory with attached housing where research can be conducted. [Selection diagram] Figure 1

Description

The present invention floats a floating wooden artificial island on the sea or a lake, grows seaweed or freshwater algae from the wooden artificial island in a culture soil unit suspended by wire, and reduces CO2 through photosynthesis of the seaweed or freshwater algae. This is an offshore research institute's proposal for a system to do this, so-called blue carbon technology.

Blue carbon is carbon that is absorbed and stored in the marine environment by the action of marine organisms. CO2 emissions from human activities amount to approximately 9.4 billion tons per year in carbon equivalent, but plants such as forests on land absorb approximately 1.9 billion tons, and the ocean as a whole absorbs approximately 2.5 billion tons, of which blue carbon ecosystems account for approximately 9.4 billion tons. It is becoming clear that CO2 absorption is approximately 1.1 billion tons.

Carbon fixed by plants on land is broken down again by microorganisms over several decades and released into the atmosphere as CO2. On the other hand, carbon accumulated on the ocean floor is decomposed very slowly, on the order of several thousand years, because the anoxic conditions prevent microorganisms from decomposing it.
Because of these characteristics, blue carbon is attracting attention as a new source of absorbing CO2, which is thought to be the cause of global warming.

Conventionally, seaweed that produces blue carbon has been left to grow in the natural environment and has been limited to shallow waters where sunlight is abundant (= 0.2% of the entire ocean). Due to the expansion of commercial facilities, the growing area may have decreased, but it has not increased.
Additionally, depending on the weather and tides, there were times when the sunlight did not reach enough, resulting in insufficient growth. Furthermore, the growth of algae could be inhibited by the occurrence of red tide.

Patent application 2017-121921

The weight of the cultivation soil unit for cultivating algae is reduced by the buoyancy of multiple sealed wooden boxes, and then suspended from multiple wooden artificial island units with four wires, and the cultivation soil unit is used to grow algae. In addition, we are conducting research to improve the varieties of algae that can perform efficient photosynthesis, as well as examining the distance from the sea surface that provides the best growth conditions for algae, and researching ways to grow algae in culture soil that has the highest nutritional value. We will create an offshore research laboratory with attached housing where studies can be conducted.

The culture soil unit is made lighter by the buoyancy of a number of sealed wooden boxes below a wooden artificial island unit floating on the ocean or between a number of wooden artificial island units, and then the culture soil unit is suspended by four wires, and algae are cultivated on the culture soil unit.
In addition, residences will be set up on the wooden artificial island to accommodate researchers and their families.

A narrow channel is set up between multiple wooden artificial island units facing the ocean current, and a large water wheel is installed along the channel. Also, an ocean current guide is set up between the wooden artificial island units, narrowing the relatively wide ocean current, increasing the flow speed of the ocean current, and rotating the large water wheel at a relatively high speed to generate wave power. (Providing electricity for research and life)

A number of electric screws controlled by AI are installed on the wooden artificial island, and by operating the electric screws, the wooden artificial island is prevented from moving due to ocean currents and its position on the GPS on the ocean is maintained.
Furthermore, if there is insufficient power to operate the screw to maintain GPS position at sea, a separate "tree-type solar power generation system" will be installed on top of the wooden artificial island.

The number of offshore research institutes conducting research on blue carbon is increasing, and through joint research and information sharing between these institutes, it is possible to discover types of algae that perform efficient photosynthesis and the conditions for their growth. By spreading blue carbon on wooden artificial islands around the world, it may be possible to achieve carbon neutrality before 2050.

An overview of the offshore research laboratory is shown. An overview of algae cultivation on a wooden artificial island is shown. An overview of the wooden artificial island is shown. An overview of wave power generation on wooden artificial islands is shown. An overview of the tree-type solar power generation system is shown.

The cultivation soil unit is made lighter by the buoyancy of multiple sealed wooden boxes, and then the cultivation soil is placed under the wooden artificial island unit floating on the ocean or between multiple wooden artificial island units using four wires. The unit is suspended, and algae are cultivated on the culture soil unit.
Additionally, a residence will be set up on the wooden artificial island so that researchers can live there.

A narrow channel is set between a plurality of wooden artificial island units in the direction of the ocean current, a large water turbine is installed along the channel, and an ocean current guide is set between the wooden artificial island units, By narrowing the flow of a relatively wide ocean current, the flow speed of the ocean current is increased, and the large water turbine is rotated at a relatively high speed to generate wave power generation.

Install multiple screws controlled by AI on the wooden artificial island and operate the screws to prevent the wooden artificial island from moving due to ocean currents and maintain its position on the GPS at sea. Make it.
In addition, if there is insufficient power to operate the screw to maintain the position on the GPS at sea, a separate tree-type solar power generation system will be installed on the wooden artificial island.

In Figure 1, the wooden artificial island unit is a wooden frame of 12m square, and the buoyancy of the necessary size and number of sealed wooden boxes from below balances the weight of the cargo on the wooden artificial island unit (see Figure 3).
The culture soil unit is a wooden frame on which soil containing nutrients necessary for the growth of algae is placed, and since it is heavy, the buoyancy balance is maintained using a number of closed wooden boxes, and the four corners of the wooden frame are hung from the wooden artificial island unit by wires.

The weight of the culture soil unit is reduced by the buoyancy of multiple sealed wooden boxes placed under the wooden artificial island unit floating on the ocean or between multiple wooden artificial island units.
The culture soil unit is suspended by four wires and algae are cultivated and researched on the culture soil unit in this offshore laboratory. Residences are set up on the wooden artificial island so that multiple researchers can live there. A narrow flow path is set between multiple wooden artificial islands toward the flow of ocean currents and large water wheels are installed along the flow path. Ocean current guides are also set up on the wooden artificial islands to narrow the wide ocean current and increase the flow speed of the ocean current, causing the large water wheels to rotate faster than the ocean current, thereby generating wave power. Multiple AI-controlled screws are installed on the wooden artificial island and the AI operates the screws, preventing the wooden artificial island from moving due to ocean currents and maintaining its position on GPS.

A number of screws controlled by AI are installed on the wooden artificial island, and the AI operates the screws to prevent the wooden artificial island from moving due to ocean currents and to maintain its GPS position on the ocean.
If the direction of the ocean current changes, the AI adjusts the balance of the operation (rotation speed) of the multiple screws and corrects the orientation of the wooden artificial island so that the rotation direction of the large water wheel always faces directly into the ocean current.
Furthermore, if there is insufficient power to operate the screw to maintain GPS position at sea, a separate tree-type solar power generation system will be installed on top of the wooden artificial island.

Figure 2 shows an overview of algae cultivation on a wooden artificial island.

Figure 3 shows an overview of the wooden artificial island.
Assemble a □12m angle with wood to form the basic unit of a wooden artificial island. Further, in FIG. 2, the wooden artificial island has six basic units, but the basic units of the wooden artificial island can be added and expanded in the direction of the arrow to make a large artificial island of several kilometers or more.
Regarding the expansion of the wooden artificial island, holes are made in the sides of the angles, the positions are determined using wooden rivets, and the angles are glued together for expansion.
That is, by expanding the wooden artificial island, it becomes possible to install many large water turbines, generators, etc., and it is possible to generate power on a larger scale.
In addition, by increasing or decreasing the number of sealed wooden boxes (cubes with sides of 2 m = approximately 8 tons of buoyancy), it is possible to balance the loading weight.

Figure 4 shows an overview of wave power generation from a wooden artificial island.
A number of wooden artificial island units are set up on the coast, and a narrow flow path of 0.6 m is set between the wooden artificial island units at right angles to the coastline. A large water wheel with a diameter of 19 m and a width of 0.4 m and equipped with paddles is set along the flow path. Also, an ocean current guide is set up on the multiple wooden artificial island units on the opposite side of the coastline, and the flow of waves approaching the coast is gradually narrowed while being guided into the narrow flow path, increasing the flow speed of the waves, which then rotates the large water wheel at a relatively high speed to generate electricity.

In addition, the shaft and bearings of the water turbine are set, and a gear is linked to the shaft of the water turbine. The gear rotates multiple gears in the gear box, and the gear box accelerates the rotation from the water turbine, allowing the generator to rotate at high speed.
In order to prevent the multiple wooden artificial islands from moving due to ocean currents, they are surrounded by multiple fixed supports that restrict the horizontal movement of the multiple wooden artificial islands, but do not restrict their vertical movement at all, and the multiple wooden artificial islands can move freely up and down in response to the ebb and flow of the tides.

Generally, ocean currents move along land, i.e. parallel to the coastline, but they have a tendency to move in shallower directions. When the water becomes shallower, resistance is created for the waves, slowing them down and causing them to move in a shallower direction, i.e. toward the coastline.
On the other hand, according to Bernoulli's theorem, "flow velocity is roughly inversely proportional to the width of the channel," so by taking the largest possible ratio, that is, by reducing the width of a 12m channel, which can be made with the size of a standard wooden artificial island unit, to 0.6m, there is a theoretical acceleration of 24 times. In reality, the flow velocity is thought to be several ten times faster in the first stage turbine, and about ten times faster in the second stage. Furthermore, because the energy of water is 770 times that of air, and the turbine rotates with a large torque, the gearbox provides acceleration, meaning that large-capacity power generation is possible 24 hours a day.

Figure 5 shows an overview of the tree-type solar power generation system.
The tree-type solar power generation system ``Patent No. 6,656,522'' has a standard type installation efficiency of 40 times that of a mega solar system, has a storage function, can withstand strong winds, and is resistant to snow and sandstorms.
It also coexists with the surrounding nature and existing buildings and does not cause environmental damage. Furthermore, if you install it on a wooden artificial island in the ocean, you don't need a foundation and just need to fix it to a wooden frame.
It is possible to estimate the amount of power generated even at sunrise or sunset (by adding reflected light from the sea).

Equipped with an Edge (AI) computer with a built-in 365-day accurate tracking angle program, you can enter the latitude of the installation location, etc., and perform on-site calibration of each wire winder (with built-in encoder). By inputting the values, automatic and accurate sunlight tracking becomes possible.
The system is configured as a unit that includes a storage battery (because it does not generate electricity at night), and an AI-equipped computer and camera, which can determine wind strength based on the swaying of trees from lamellar images, and snowfall conditions. Therefore, store the light-receiving panel in a storage box or make the light-receiving panel slightly vertical.
The AI and smartphone are connected via Wi-Fi communication, and manual operation is possible using the smartphone app.Each panel is moved to an easy-to-clean position, and the worker cleans the solar panel with a brush while spraying water on it. be able to.

The number of offshore laboratories researching blue carbon is increasing, and through joint research and information sharing among multiple offshore laboratories, the types and growth conditions for algae that perform efficient photosynthesis have been discovered, and wooden artificial islands are being built all over the world. By deploying blue carbon, there is a possibility of achieving carbon neutrality before 2050.

Claims (1)

The weight of the cultivation soil unit is reduced by the buoyancy of multiple sealed wooden boxes on the underside of a wooden artificial island unit floating on the ocean or between multiple wooden artificial island units.
This is an offshore research laboratory where the cultivation soil unit is suspended by four wires and algae cultivation and research are carried out on the cultivation soil unit.A residence is set up on the wooden artificial island, and multiple researchers are housed on the island. It is an offshore research laboratory that is designed to be habitable, with narrow channels set between multiple wooden artificial islands in the direction of ocean currents, and large water turbines installed along the channels. This is an offshore research institute that generates wave power by setting ocean current guides to narrow the wide ocean current, increasing the velocity of the ocean current, and rotating the large water turbine at a higher speed than the ocean current. Install multiple AI-controlled screws in
An offshore laboratory where the AI can operate the screw, prevent the wooden artificial island from moving due to ocean currents, and maintain its position on the GPS.