JP4993672B2 - Algae cultivation apparatus and algae cultivation method - Google Patents

Description

  The present invention relates to an algae cultivation apparatus and an algae cultivation method for cultivating algae.

  Conventionally, as shown in Patent Document 1, a method of promoting cultivation by supplying carbon dioxide to seaweed has been considered.

However, the present inventor has discovered that if carbon dioxide is simply supplied and dissolved, the pH of seawater becomes acidic and the algae wither.
JP 2002-262858 A

  Accordingly, the present invention aims to provide an algae cultivation apparatus and method for solving the problems that occur when supplying carbon dioxide to seawater to increase the efficiency of algae cultivation and at the same time providing carbon dioxide. It is what.

That is, the algal cultivation apparatus according to the present invention includes a cultivation tank for storing seawater to grow algae, and a bubble generator for supplying carbon dioxide to the seawater in the cultivation tank as nanobubbles or microbubbles. A carbon supply mechanism and an electrolysis mechanism that electrolyzes seawater in the cultivation tank, and the bubble generator generates nanobubbles or microbubbles by aerating carbon dioxide through a hollow structure having fine pores. It is a thing to do. Here, “seawater” is a concept including natural seawater collected from the sea and artificially generated seawater. The “algae” are seaweeds mainly inhabiting seawater, and examples thereof include brown algae such as kombu, wakame, hijiki and mozuku, red algae such as cassava and proboscis, and green algae such as aosa and aonori.

  If it is such, since carbon dioxide is supplied to seawater, the growth of algae can be promoted. Moreover, by dissolving carbon dioxide in seawater, the pH of the seawater becomes acidic, but by electrolyzing the seawater, this pH can be maintained at a weak alkali which is the pH of the seawater. . Therefore, carbon dioxide is supplied to seawater to increase the efficiency of algae cultivation, and problems caused when carbon dioxide is supplied can be solved.

Here, the chemical reaction formula when carbon dioxide is dissolved in seawater is shown below. First, carbon dioxide dissolved in seawater is dissociated in seawater and releases hydrogen ions to become bicarbonate ions (HCO ₃ ⁻ ) or carbonate ions (CO ₃ ²⁻ ). From this, it is understood that when carbon dioxide is dissolved in seawater, hydrogen ions increase in the seawater and the pH changes to acidic.

CO ₂ + H ₂ O → H ₂ CO ₃ (1)
H ₂ CO ₃ → H ⁺ + HCO ₃ ⁻ (2)
HCO ₃ ⁻ → H ⁺ + CO ₃ ⁻ (3)

  Specifically, it is desirable that the electrolysis mechanism adjusts the pH of the seawater to pH 7.5 to 8.5 suitable for algae growth.

  As a specific embodiment of the electrolysis mechanism, it is conceivable that the electrolysis mechanism includes an electrode immersed in the seawater and a power source for supplying current to the electrode.

  If it is such, the following electrode reaction will arise in an anode and a cathode, respectively, and seawater can be adjusted now to pH7.5-8.5.

Anode electrode reaction:
2H ₂ O = O ₂ + 4H ⁺ + 4e ⁻ (4)
2Cl ⁻ = Cl ₂ + 2e ⁻ (5)
2HOCl + 2H ⁺ + 2e ⁻ = Cl ₂ + 2H ₂ O (6)

Cathode electrode reaction:
2H ₂ O + 2e ⁻ = H ₂ + 2OH ⁻ (7)
O ₂ + 2H ₂ O + 2e ⁻ = H ₂ O ₂ + 2OH ⁻ (8)
H ₂ O ₂ + 2e ⁻ = 2OH ⁻ (9)

  In consideration of the fact that electrolysis can be performed even with a very small amount of current, as a specific embodiment of the power source, the power source generates power using natural power such as a solar cell or a wind power generator. It is desirable to be.

  In order not only to supply carbon dioxide to seawater to make algae easy to grow, but also to reduce the temperature of seawater to a water temperature suitable for algae to grow, the carbon dioxide supply mechanism is liquefied. It is desirable to supply carbon dioxide. If this is the case, the temperature of the liquefied carbon dioxide itself increases even during the supply, but it is still a low temperature, so it is possible to prevent the temperature of the seawater from rising or to lower the water temperature.

  In order to facilitate the dissolution of carbon dioxide in seawater, the carbon dioxide supply mechanism preferably includes a bubble generator that converts carbon dioxide supplied to the seawater into nanobubbles or microbubbles. Microbubbles are microbubbles having a diameter of 50 μm or less, and nanobubbles are ultrafine bubbles having a diameter of less than 1 μm. Microbubbles and nanobubbles have not only an action of improving the gas absorption rate into algal cells but also a bactericidal action and a water quality purification action. Therefore, by making it easy to disperse molecular carbon dioxide in seawater, it is possible not only to promote the uptake of carbon dioxide into cells and activate photosynthesis, but also to clean the algae cultivation environment.

In addition, the algal cultivation method according to the present invention supplies carbon dioxide as nanobubbles or microbubbles to a cultivation tank for storing seawater and cultivating algae, and electrolyzes the seawater in the cultivation tank in the seawater. The algae cultivation method of adjusting the pH of the algae is characterized in that the bubble generator generates nanobubbles or microbubbles by aeration of carbon dioxide through a hollow structure having fine pores .

  If it is such, while supplying carbon dioxide to seawater, cultivation of algae can be promoted, and by supplying carbon dioxide, seawater becomes acidic and the algae wither. Can be prevented.

  As carbon dioxide used for the cultivation method, liquefied carbon dioxide is preferable. Thereby, the temperature of seawater can be reduced and it can be set as the suitable environment for growth of algae.

  As a specific method for supplying carbon dioxide, it is desirable to supply the carbon dioxide as nanobubbles or microbubbles. If it is such, it will become easy to disperse | distribute molecular carbon dioxide in seawater, and it will become easy to be absorbed and utilized by the algal cell.

  Thus, according to the present invention, since carbon dioxide is supplied to seawater, the growth of algae can be promoted. In addition, when carbon dioxide is dissolved in seawater, the pH of the seawater becomes acidic and the algae die, but by electrolyzing the seawater, this pH can be maintained at a weak alkali that is the pH of the seawater. .

  Next, an embodiment of the algal cultivation apparatus according to the present invention will be described with reference to the drawings.

  As shown in FIG. 1, the algal cultivation apparatus 1 of the present embodiment includes a cultivation tank 2 for cultivating seaweed S such as seaweed, and a carbon dioxide supply mechanism 3 that supplies carbon dioxide to seawater in the cultivation tank 2. And an electrolysis mechanism 4 for electrolyzing seawater in the cultivation tank 2.

  The cultivation tank 2 is for cultivating seaweed S, and stores seawater while storing seawater. And the cultivation tank 2 is installed in the sea or the sea, for example. In addition, the seaweed S is hold | maintained on the cultivation bed SH which can be taken out from the cultivation tank 2 outside.

  An illuminating device 5 having red, green, and blue LED groups 51 is provided above or below the seaweed S accommodated in the cultivation tank 2. Thereby, the seaweed S can be cultivated only by artificial light without using sunlight in combined use of sunlight and artificial light such as LED or in a closed system. Further, artificial light or sunlight from an artificial light source such as an LED provided outside the cultivation tank 2 may be guided and irradiated into the cultivation tank 2 using an optical fiber.

  Furthermore, a photodetector 6 that detects light from the LED group 51 is provided at the bottom of the cultivation tank 2. The photodetector 6 outputs a light detection signal to the light control unit 71 (see FIG. 2) of the control device 7. And the light control part 71 adjusts the light quantity etc. of the LED group 51 of the illuminating device 5 based on the light detection signal.

  The carbon dioxide supply mechanism 3 is provided on a liquid carbon dioxide storage tank 31 that stores liquid carbon dioxide, a distribution pipe 32 that distributes liquid carbon dioxide from the tank 31 to the cultivation tank 2, and the distribution pipe 32. And a bubble generator 33 for supplying carbon in nanobubbles. On the distribution pipe 32, a pump 34 for distributing liquid carbon dioxide from the tank 31 to the cultivation tank 2 is provided.

  As the bubble generator 33, a method by pressure dissolution (a method in which a larger amount of gas is dissolved by pressurization to generate by using cavitation, etc.), a method by ultrasonic waves (bubbles are excited by applying ultrasonic waves) Using a shearing method (a method of blowing a gas into a violent flow and tearing the gas to make bubbles fine), a method using a shock wave (a method using a shock wave generated by a Benchery tube) Conceivable. In this embodiment, carbon dioxide is made into nanobubbles by allowing carbon dioxide to pass through a hollow structure having fine pores.

  The carbon dioxide supply mechanism 3 includes a hydrogen ion concentration detector 35 that detects the hydrogen ion concentration in the seawater in the cultivation tank 2. The hydrogen ion concentration detector 35 outputs a concentration detection signal to the concentration control unit 72 (see FIG. 2) of the control device 7. The concentration control unit 72 controls the pump 34 of the carbon dioxide supply mechanism 3 based on the concentration detection signal to control the supply amount of carbon dioxide, or controls the power source 42 of the electrolysis mechanism 4. In addition, the carbon dioxide concentration in the atmosphere just above the water surface is monitored to adjust the amount of carbon dioxide aeration.

  The electrolysis mechanism 4 electrolyzes the seawater in the cultivation tank 2 and adjusts its pH to be weakly alkaline, and a pair of electrodes 41 immersed in the seawater in the cultivation tank 2 and the electrodes 41 And a power supply 42 for supplying current. Specifically, the pH is adjusted to a pH (pH 7.5 to 8.3) suitable for the seaweed S to grow.

  In the present embodiment, the pair of electrodes 41 uses a conductor such as platinum or iridium for both the cathode and the anode. The power source 42 uses a solar cell that is a DC power source. Thereby, the seaweed S can be cultivated without requiring electric power from the outside of the apparatus. In addition, since a direct current power source is used, a rectifier is not required to pass a direct current through the pair of electrodes 41.

  As mentioned above, according to the algal cultivation apparatus 1 of this embodiment, since carbon dioxide is supplied and dissolved in seawater, the growth of seaweed S can be promoted. Moreover, since the seawater is electrolyzed by the electrolysis mechanism 4 and adjusted to weak alkalinity (pH 7.5 to 8.2), the seaweed S will wither by supplying too much carbon dioxide to the seawater. Can be prevented.

  Furthermore, since carbon dioxide is supplied as nanobubbles, molecular dispersion of carbon dioxide in seawater is promoted, and absorption of carbon dioxide into algal cells and photosynthesis efficiency can be enhanced.

  In addition, since a power source using natural energy such as a solar cell is used as the power source 42 of the electrolysis mechanism 4, the seaweed S can be cultivated without requiring power from the outside of the apparatus.

  In addition, since liquid carbon dioxide is used, the temperature of the seawater can be lowered by the temperature of the carbon dioxide itself, which is suitable for the growth of the seaweed S. In addition, since it is cultivated in the cultivation tank 2, the seaweed S can be protected from external enemies.

  The present invention is not limited to the above embodiment.

  For example, in the above-described embodiment, the cultivation tank 2 is installed in the sea to cultivate the seaweed S. However, the cultivation tank 2 may be installed on the land and cultivated.

  Moreover, in the said embodiment, although the power supply was a solar cell, what used the wind power generator, the hydroelectric generator, or the tidal power generator etc. which change the energy which seawater moves by tidal current etc. into others. It may be. Alternatively, a commercial power source may be used. In this case, a rectifier that converts alternating current into direct current is required.

  Further, in the above embodiment, carbon dioxide is liquid carbon dioxide, but exhaust carbon dioxide may also be used. If this is the case, carbon dioxide in the atmosphere can be reduced, which can be one of the solutions to environmental problems.

  In addition, the bubble generator of the above embodiment generates nanobubbles, but may generate microbubbles.

  In addition, in the above-described embodiment, the pair of electrodes uses a conductor such as platinum or iridium for both the anode and the cathode. However, a magnesium alloy (Mg) can be used for the cathode, and silver chloride (AgCl) can be used for the anode. .

  In addition, in the above-described embodiment, the bubble generator and the electrolysis mechanism are separately provided. However, the hollow structure of the bubble generator in the above-described embodiment is formed from a conductive material and is also used as an electrode. You can also

  In addition, some or all of the above-described embodiments and modified embodiments may be combined as appropriate, and the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the spirit of the present invention. .

The schematic block diagram of the algae cultivation apparatus which concerns on one Embodiment of this invention. The function block diagram of the control apparatus in the embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Algal cultivation apparatus 2 ... Cultivation tank 3 ... Carbon dioxide supply mechanism 31 ... Bubble generator 32 ... Distribution pipe 33 ... Bubble generator 34 ... Pump 35 ... Concentration detector 4 ... Electrolysis mechanism 41 ... Electrode 42 ... Power source (solar cell)
DESCRIPTION OF SYMBOLS 5 ... Illuminating device 51 ... LED group 6 ... Photo detector 7 ... Control device 71 ... Light control part 72 ... Concentration control part

Claims (5)

A cultivation tank for storing seawater and cultivating algae,
A carbon dioxide supply mechanism having a bubble generator for supplying carbon dioxide to the seawater in the cultivation tank as nanobubbles or microbubbles,
An electrolysis mechanism for electrolyzing seawater in the cultivation tank ,
An algae cultivation apparatus in which the bubble generator generates nanobubbles or microbubbles by aeration of carbon dioxide through a hollow structure having fine holes .   The algal cultivation apparatus according to claim 1, wherein the electrolysis mechanism adjusts the pH of the seawater to 7.5 to 8.5.   The algae cultivation apparatus according to claim 1 or 2, wherein the electrolysis mechanism includes an electrode immersed in the seawater and a power source for supplying current to the electrode.   The algal cultivation apparatus according to claim 1, 2, or 3, wherein the hollow structure of the valve generator is formed of a conductive material and serves also as an electrode of the electrolysis mechanism. While supplying carbon dioxide as nanobubbles or microbubbles to a cultivation tank for storing seawater and cultivating algae, it is an algae cultivation method that electrolyzes the seawater in the cultivation tank to adjust the pH in the seawater ,
An algae cultivation method in which the bubble generator generates nanobubbles or microbubbles by aeration of carbon dioxide through a hollow structure having fine pores.