JP2022147291A - Purification method for pond - Google Patents

Abstract

To provide a pond purification method capable of reducing a turbidity of ponds (e.g., artificial ponds that are green in color on a golf course), which are highly turbid due to phytoplankton, at low cost, simply, and in a short period of time, without causing problems such as increased chromaticity of ponds, offering better scenery.SOLUTION: A method of pond purification includes a sedimentation substance supply process in which a sedimentation substance (an algicide, powder consisting of calcium silicate-containing material, or concrete sludge recycled powder) is supplied to the pond to sediment phytoplankton to reduce its turbidity, and a powder supply process in which, at least five days after the sedimentation substance has been supplied, powder consisting of calcium silicate-containing material is supplied to the pond to control an increase in chromaticity due to phytoplankton detritus.SELECTED DRAWING: None

Description

The present invention relates to a pond cleaning method.

An artificial pond in a golf course is one of course design means for adjusting the difficulty of golf.
In addition, artificial ponds in golf courses also play a role of storing water for sprinkling the lawn and a role of providing an excellent landscape on the golf course.
However, artificial ponds in golf courses sometimes appear green due to phytoplankton (eg, green algae, cyanobacteria, etc.) and the like. In this case, the landscape deteriorates, so it becomes necessary to purify the water in the artificial pond.

As a golf course pond purification system, for example, Patent Document 1 discloses a golf course purification system for purifying water in a viewing pond provided in a golf course. A golf course purification system is described that includes a purification device that returns to the pond to create an area of purified water in a predetermined portion of the viewing pond.
On the other hand, water purification materials containing calcium silicate-containing materials are known as water purification materials.
For example, Patent Document 2 describes a water purification material containing a calcium silicate-containing material and zeolite, wherein each of the base substitution capacity and the phosphate absorption coefficient is within a specific numerical range. there is

JP-A-3-275186 JP 2020-157247 A

The golf course purification system described in Patent Document 1 requires a purification device. The introduction and maintenance of this purifier requires a lot of cost and a considerable amount of time and effort.
The water purification material described in Patent Document 2 solves the problem that water quality deteriorates due to the excrement of aquatic organisms in aquaculture ponds for shrimp and other aquatic organisms. By promoting the growth of diatoms in water by the ability to supply acid, the growth of aquatic organisms such as shrimp that feed on diatoms is improved. This water purification material can be said to purify the water quality in terms of reducing the concentration of ammonia and phosphoric acid, but it does not reduce the turbidity of the water in the aquaculture pond in terms of promoting the growth of diatoms.

An object of the present invention is to reduce the turbidity of a pond whose turbidity is high due to phytoplankton (for example, an artificial pond exhibiting a green color in a golf course) without causing problems such as an increase in the chromaticity of the pond. To provide a method for cleaning a pond, which is low-cost, easy, and can be reduced in a short period of time to provide a better landscape.

As a result of intensive studies to solve the above problems, the present inventors have found that after supplying a sedimentation substance for sedimenting phytoplankton to a pond whose turbidity is high due to phytoplankton, at least 5 days The present inventors have found that the above object can be achieved by supplying a powder of a calcium silicate-containing material to this pond, and completed the present invention.
The present invention provides the following [1] to [6].

[1] A sedimentation substance supply step of supplying a sedimentation substance for sedimenting the phytoplankton to a pond whose turbidity is high due to phytoplankton to reduce the turbidity of the pond; A powder comprising a calcium silicate-containing material is supplied to the pond after at least five days have passed since the substance was supplied, thereby suppressing an increase in the color of the pond due to the dead phytoplankton. A method for cleaning a pond, comprising: a supplying step.
[2] After the turbidity of the pond decreased between the sedimentation substance supply step and the powder supply step, it was confirmed that the chromaticity of the pond increased due to the dead phytoplankton. and a powder supply timing determination step of determining the timing at which the powder made of the calcium silicate-containing material should be supplied in the powder supply step.
[3] The above [1] or [2], wherein the sedimentation substance used in the sedimentation substance supply step is an algicide, a powder made of a calcium silicate-containing material, or a recycled concrete sludge powder. How to clean a pond.
[4] The sedimentation substance used in the sedimentation substance supply step is an algaecide, and the powder made of the calcium silicate-containing material used in the powder supply step is porous calcium silicate water. The method for cleaning a pond according to the above [3], wherein the powder is composed of a solute and contains 10% by mass or more of the powder having a particle size of 10 µm or less.
[5] The sedimentation substance used in the sedimentation substance supply step and the powder made of the calcium silicate-containing material used in the powder supply step are porous calcium silicate hydrates, and have a diameter of 10 μm or less. The method for cleaning a pond according to the above [3], wherein the ratio of the powder having a particle size of is 10% by mass or more.
[6] The method for purifying a pond according to any one of [1] to [5] above, wherein the pond is an artificial pond for a golf course.

According to the present invention, the turbidity of a pond whose turbidity is high due to phytoplankton (for example, an artificial pond exhibiting a green color in a golf course) can be reduced without causing problems such as an increase in the chromaticity of the pond. , can be reduced at low cost, easily, and in a short period of time. A pond with reduced turbidity in this way can provide a better landscape.

A method for purifying a pond of the present invention includes a step of supplying a sedimentation substance for sedimenting the phytoplankton into a pond in which turbidity is high due to phytoplankton, and a step of supplying the sedimentation substance. a powder supply step of supplying a powder made of a calcium silicate-containing material to the pond after at least five days have passed since the time of the injection to suppress an increase in the chromaticity of the pond caused by the dead phytoplankton. include.
In the method for purifying a pond of the present invention, after the turbidity of the pond has decreased between the sedimentation substance supply step and the powder supply step, the chromaticity of the pond due to the dead phytoplankton is increased. A powder supply timing determination step of confirming that the powder is occurring and determining when to supply the powder made of the calcium silicate-containing material in the powder supply step can be included.
Hereinafter, each step will be described in detail in the order of the sedimentation substance supply step, the powder supply timing determination step, and the powder supply step.

[Sedimentation substance supply step]
The sedimentation substance supply step is a step of supplying a sedimentation substance for sedimenting phytoplankton to a pond whose turbidity is high due to phytoplankton, thereby reducing the turbidity of the pond.
In the present invention, a pond to be purified is a pond with high turbidity due to phytoplankton.
Examples of phytoplankton include green algae and cyanobacteria.
A pond with high turbidity due to phytoplankton usually also has high chromaticity due to substances generated from dead phytoplankton that have sunk to the bottom of the water.

Examples of ponds include artificial ponds in golf courses, artificial ponds in parks, and artificial ponds in botanical gardens.
Of these, artificial ponds in golf courses are preferable because the area and depth of the ponds are suitable for applying the method of the present invention.
The turbidity of the pond to be purified is preferably 20 degrees or more, more preferably 25 degrees or more, and particularly preferably 30 degrees or more, from the viewpoint of sufficiently obtaining the effect of the present invention (turbidity reduction).
The upper limit of the turbidity is not particularly limited, but from the viewpoint of sufficiently obtaining the effect of the present invention (especially ensuring a good landscape after purification), it is preferably 100 degrees, more preferably 80 degrees, and particularly preferably is 60 degrees.

In the present invention, the turbidity is a value measured by the "perspective turbidity method" specified as the "test method for turbidity" in the "Test Method for Water Supply 2011 Edition" (Japan Water Works Association). Say.
In the present invention, 1 degree of turbidity (unit: degree) by fluoroscopic nephelometry is equivalent to turbidity when 1 mg of formazin, a standard substance, is contained in 1 liter of purified water.

The chromaticity of the pond to be purified is preferably 5 degrees or more, more preferably 7 degrees or more, particularly preferably 7 degrees or more, from the viewpoint of significantly reducing turbidity and chromaticity to emphasize the effect of improving the landscape. 9 degrees or more.
Although the upper limit of the chromaticity is not particularly limited, it is preferably 30 degrees, more preferably 25 degrees, and particularly preferably 20 degrees from the viewpoint of sufficiently obtaining the effects of the present invention (better scenery).
In the present invention, chromaticity refers to a value measured by the "transmitted light measurement method" specified as the "method for testing chromaticity" in "Test Method for Water Supply, 2011 Edition". However, when measuring chromaticity, pond water from which suspended solids (SS) have been removed shall be used.
The transmitted light measurement method is a method of measuring the degree of pale yellow to yellowish brown color exhibited by soluble substances and colloidal substances contained in water by absorptiometry at a wavelength of around 390 nm.

Examples of sedimentation substances include algicides, powders of calcium silicate-containing materials, concrete sludge regeneration powders, and the like.
Algicides kill phytoplankton in water. Dead phytoplankton sink to the bottom.
As the algicidal agent, one that is non-toxic or weakly toxic to fish is preferred. From this point of view, an example of a preferable algicidal agent is "Torumo Up" (trade name; manufactured by Sanmei Chemical Co., Ltd.; "Torumo Up" is a registered trademark).
When using such a preferable algicidal agent, it is possible to put fish such as carp, crucian carp, killifish, etc. in the pond to suppress the occurrence of mosquito larvae and mosquitoes in summer.
When using an algicidal agent that is highly toxic to fish, it is desirable to keep aquatic organisms such as fish out of the pond to which the method of the present invention is applied.

The powder of calcium silicate-containing material adheres to phytoplankton in water and settles with the phytoplankton to the bottom of the water. The settled phytoplankton later die.
Examples of materials that constitute powders of calcium silicate-containing materials include tobermorite, xonotlite, CSH gel, foshagite, gyrolite, hillbrandite, wollastonite, and the like.
Among them, tobermorite is preferable from the viewpoint of availability and economy.

Tobermorite is a crystalline calcium silicate hydrate.
Natural minerals may be used as tobermorite, but from the viewpoint of easy availability, it is preferable to use lightweight cellular concrete (ALC) containing tobermorite as a main component.
Moreover, from the viewpoint of promoting the use of waste materials, it is more preferable to use offcuts of lightweight cellular concrete generated in the manufacturing process of lightweight cellular concrete or at construction sites.
Lightweight cellular concrete consists of tobermorite and unreacted silica stone and has a porosity of about 80% by volume. Here, the porosity refers to the ratio of the total volume of voids to the total volume of concrete.
The ratio of tobermorite in the lightweight cellular concrete is usually about 65 to 80% by volume based on 100% by volume of the solid phase as a whole, excluding voids inside the lightweight cellular concrete.

The particle size distribution of the powder made of the calcium silicate-containing material is preferably such that the proportion of powder having a particle size of 10 μm or less is 10% by mass or more (preferably 20% by mass or more, more preferably 30% by mass or more). . If the particle size exceeds 10 μm, it becomes difficult to settle the phytoplankton. When the ratio is less than 10% by mass, the amount of sedimentation of phytoplankton per unit mass of the powder made of the calcium silicate-containing material is reduced.
The amount of the calcium silicate-containing powder used is preferably 0.1 to 10 kg, more preferably 0.3 to 7 kg, even more preferably 0.5 to 5 kg, and particularly preferably 1 kg per 10 m ² of pond area. ~3 kg. When the amount is 0.1 kg or more, a larger amount of phytoplankton is killed by sinking. When the amount is 10 kg or less, the cost of materials used in the method of the present invention can be reduced, and the large amount of powder used causes a temporary excessive increase in turbidity of pond water. can be avoided.

The recycled concrete sludge powder adheres to phytoplankton in water and sinks to the bottom of the water together with the phytoplankton. The settled phytoplankton later die.
Concrete sludge recycled powder is the solid content obtained by diluting concrete sludge (which should be treated as waste, etc., generated in the manufacturing process of concrete products by centrifugal molding, etc.) with water, followed by solid-liquid separation with a filter press. can be obtained by drying, crushing or pulverizing, and then classifying.
The preferred particle size distribution of the recycled concrete sludge powder is the same as the particle size distribution of the powder comprising the calcium silicate-containing material described above.
Examples of commercial products of recycled concrete sludge powder include "PAdeCS" (trade name; manufactured by Nippon Concrete Industry Co., Ltd.; "PAdeCS" is a registered trademark).
The width of the decrease in pond turbidity due to the supply of the sedimentation substance (in other words, the value obtained by subtracting the turbidity value after supply from the turbidity value before supply) is preferably 8 degrees or more, more preferably 12 degrees or more, particularly preferably 16 degrees or more.

[Powder supply timing determination step]
In the powder supply timing determination step, in the pond after the sedimentation substance is supplied in the previous step (sedimentation substance supply step), after the turbidity of the pond is reduced, the chromaticity of the pond is increased due to dead phytoplankton. It is a step of confirming that the is occurring and determining the time to supply the powder composed of the calcium silicate-containing material in the subsequent step (powder supply step).
Since the phytoplankton settles to the bottom of the water in the previous step (the step of supplying the sedimentation substance), the turbidity of the pond is significantly lower immediately after the previous step than before the previous step.
However, the settled phytoplankton corpses leach substances that color pond water.
Therefore, the chromaticity of the pond increases with the death of phytoplankton.
In this step, in order to prevent the chromaticity of the pond from increasing (preferably reducing the chromaticity) due to such dead phytoplankton, the timing of the subsequent powder feeding step is determined.

The period from when the sedimentation substance is supplied in the pre-process (precipitation substance supply step) to when the powder composed of the calcium silicate-containing material is supplied in the post-process (powder supply step) is 5 days or more, preferably 10 days or longer, preferably 15 days or longer. If the period is less than 5 days, the degree of increase in the chromaticity of the pond due to dead phytoplankton is slight, and the effects of the present invention cannot be sufficiently obtained.
Although the upper limit of the above period is not particularly limited, it is usually 50 days. Especially in the summer, the upper limit of said period is usually 30 days.

[Powder supply step]
In the powder supply step, after at least five days have passed since the sedimentation substance was supplied in the sedimentation substance supply step, the powder made of the calcium silicate-containing material is supplied to the pond to produce phytoplankton. This is a step for suppressing an increase in the chromaticity of the pond due to carcasses.
The calcium silicate-containing material powder used in this step is the same as the calcium silicate-containing material powder used in the sedimentation substance supply step.
The amount of the calcium silicate-containing powder used is preferably 0.1 to 10 kg, more preferably 0.3 to 7 kg, even more preferably 0.5 to 5 kg, and particularly preferably 1 kg per 10 m ² of pond area. ~3 kg. When the amount is 0.1 kg or more, an increase in the chromaticity of the pond can be more sufficiently suppressed. If the amount is 10 kg or less, the cost of the material used in the method of the present invention can be reduced, and the large amount of powder used causes a temporary excessive increase in pond water turbidity. can be avoided.

The chromaticity of the pond after supplying the powder composed of the calcium silicate-containing material in this step is preferably 9 degrees or less, more preferably 7 degrees or less, even more preferably 5 degrees or less, and particularly preferably 3 degrees or less.
In addition, the width of the decrease in the chromaticity of the pond (in other words, the value obtained by subtracting the chromaticity value after powder supply from the chromaticity value before powder supply) is preferably 2 degrees or more, more preferably It is 4 degrees or more, more preferably 5 degrees or more, and particularly preferably 6 degrees or more.

EXAMPLES The present invention will be specifically described below by way of examples, but the present invention is not limited to these examples.
[Materials used]
(1) Powder made of calcium silicate-containing material (ALC powder)
Powders (ALC powders) obtained by crushing and classifying waste materials of lightweight cellular concrete (ALC) were used as the calcium silicate-containing material powders.
The ALC powder was a powder in which the ratio of powder having a particle size of 10 μm or less was about 30 to 40% by mass. The maximum particle size of the ALC powder was 100 μm or less.
(2) Algae removal agent As the algae removal agent, "Torumo Up" (trade name; manufactured by Sanmei Chemical Co., Ltd.) was used.

[Example 1]
The method of the present invention was applied as follows to an artificial pond in a golf course (a pond that is green due to the presence of phytoplankton). Note that Example 1 was conducted in the summer from late June to late July.
First, in an artificial pond (turbidity: 30 degrees; chromaticity: 9.0 degrees) of a golf course, an amount of 6 g per unit mass of the pond (however, the mass of the pond depends on the area and depth of the pond) ) was sprayed.
After spraying the algicide, the chromaticity of the pond clearly decreased visually, but after that, the chromaticity of the pond clearly increased visually. , the artificial pond was sprinkled with ALC powder in an amount of 2 kg per unit area of 10 m ² of said pond.
At this time, when the turbidity of the pond was measured immediately before the ALC powder was sprayed, the turbidity was 7.0 degrees. Moreover, the chromaticity at this time was 8.5 degrees.
Eight days after the ALC powder was sprayed, the chromaticity of the pond was measured and found to be 3.0 degrees. Moreover, the turbidity at this time was 6.5 degrees.

[Example 2]
The method of the present invention was applied as follows to an artificial pond of a golf course different from that of Example 1 (a pond exhibiting green color due to the presence of phytoplankton). In addition, Example 2 was carried out from late August to mid-September.
First, an artificial pond (turbidity: 25 degrees; chromaticity: 9.0 degrees) of a golf course was sprayed with 2 kg of ALC powder per unit area of 10 m ² of the pond.
Although the chromaticity of the pond clearly decreased after the ALC powder was sprayed, the chromaticity of the pond increased visually afterward. 2 kg of ALC powder per unit area of 10 m ² of the pond was sprayed again (second time).
At this time, when the turbidity of the pond was measured immediately before the ALC powder was sprayed (second time), the turbidity was 8.0 degrees. Moreover, the chromaticity at this time was 8.5 degrees.
Five days after the ALC powder was sprayed, the chromaticity of the pond was measured and found to be 3.0 degrees. Moreover, the turbidity at this time was 6.0 degrees.

As shown in Examples 1-2, by using the method of the present invention, a pond with a turbidity of 25-30 degrees and a chromaticity of 9.0 degrees, a pond with a turbidity of 6.0-6.5 degrees Moreover, the pond could be changed to a pond with a chromaticity of 3.0 degrees in a short period of less than one month.
In addition, the pond purified by the method of the present invention can maintain the turbidity and chromaticity below a certain level by repeating the method of the present invention.

Claims (6)

A sedimentation substance supply step of supplying a sedimentation substance for sedimenting the phytoplankton to a pond whose turbidity is high due to phytoplankton to reduce the turbidity of the pond;
After at least 5 days have elapsed since the sedimentation material was supplied, the pond is supplied with a powder comprising a calcium silicate-containing material to prevent an increase in the color of the pond due to the dead phytoplankton. suppressing powder feeding process,
A method for cleaning a pond, comprising: Between the sedimentation substance supply step and the powder supply step,
After the turbidity of the pond has decreased, it is confirmed that the chromaticity of the pond has increased due to the dead phytoplankton, and the powder composed of the calcium silicate-containing material is supplied in the powder supply step. A powder supply timing determination step for determining when to
The method of cleaning a pond according to claim 1, comprising: 3. The pond cleaning method according to claim 1 or 2, wherein the sedimentation substance used in the sedimentation substance supplying step is an algae remover, a calcium silicate-containing material powder, or a recycled concrete sludge powder. The sedimentation substance used in the sedimentation substance supply step is an algaecide, and the powder made of the calcium silicate-containing material used in the powder supply step is composed of porous calcium silicate hydrate. 4. The method for cleaning a pond according to claim 3, wherein the ratio of the powder having a particle size of 10 [mu]m or less is 10% by mass or more. The sedimentation substance used in the sedimentation substance supply step and the powder composed of the calcium silicate-containing material used in the powder supply step are composed of porous calcium silicate hydrate, and have a particle size of 10 μm or less. 4. The method for cleaning a pond according to claim 3, wherein the powder has a ratio of 10% by mass or more. The method for purifying a pond according to any one of claims 1 to 5, wherein the pond is an artificial pond of a golf course.