JP2012179056A - Method of developing artificial reed field - Google Patents

Abstract

PROBLEM TO BE SOLVED: To develop an artificial reed field in a brackish water region by planting reeds not to wither up even with salinity of the brackish water region.SOLUTION: The method of developing the artificial reed field artificially develops the reed field in the brackish water region A, and sets the ground height of the artificial reed field B under conditions where the salinity of groundwater in the reed rooting zone satisfies the growing limitation of the reed, calculates the salinity of the groundwater in the reed rooting zone in consideration of a drying ratio of the reed rooting zone with respect to a tidal level of the brackish water region of a planned development site, and averages during the predetermined period of time calculated assuming the salinity is 0 when dried more than the tidal level of the brackish water region of the planned development site.

Description

  The present invention relates to a technique for artificially planting a reed in a brackish water area where fresh water and seawater are mixed, and particularly a technique for artificially creating a reed growth environment without being damaged by salt.

  In recent years, pollution of the water environment has become significant and has become a major social problem. For example, in large lakes and the like, residential land around the lakes is rapidly advancing, and the lakes are eutrophied due to domestic wastewater such as washing water and miscellaneous wastewater drained from the living environment, and pollution is progressing. Some coastal fisheries, such as lakes, which were supported by abundant fishery resources, have been forced to close due to a sharp decline in fishery resources due to deterioration in water quality.

  Improvement of such a pollution situation is an urgent issue, and many improvement methods have been proposed so far. Among these various improvement methods, recently, the role played by waterside purification of reeds, which are waterside plants, has been reviewed. Traditionally, many reeds that have grown naturally around lakes and rivers have disappeared due to the recent development of residential land around lakes and rivers.

  However, recent research has revealed that the reeds of the reed field have been used to purify the water quality of the lake where the reed field is located.

  Therefore, efforts have been made to artificially reproduce the reed field in lakes where water quality has deteriorated. An attempt to artificially create a conventional reed field is to construct a dam or earthen that separates the surrounding area from the surrounding area, place planted soil inside the dam or earthen, and plant the reed on this planted soil. Or it was carried out by planting with an underground stem.

  Incidentally, Yoshi is written in Chinese characters “葦” and is also called “ashi”.

  However, in the conventional method for creating artificial reed fields, the reed growth method has been well established in freshwater bodies such as rivers and freshwater lakes, but in freshwater and seawater mixed brackish waters. In many cases, it could not be applied as it was. This is because the growth of reed is inhibited by salt in brackish water.

  Conventionally, what is the composition of the planting floor structure (soil quality, ground height) for planting reeds in response to salinity and tide level fluctuations in local brackish waters where artificial reed fields are to be artificially created? There was no clear standard of preference. The planting situation in freshwater has been applied on a trial and error basis, and the reed field has been restored in brackish water.

  Therefore, the artificial reed field of the conventional structure provided in the brackish water area is affected by the salinity in the brackish water, and it is difficult for the reed to grow reliably because the reed is withered by the salt in the water. That is, in the past, the salt tolerance of reeds and the criteria for selecting the right place were not clear.

  The inventors of the present invention clarified the standards for the creation of such reeds to minimize the damage of the salt on the growth of reeds, to actively create reeds, and to purify water quality in a natural way. I thought it was necessary to proceed strongly.

  At the same time, the artificial reed field of the conventional configuration uses landscaping soil for horticulture as planting soil, and it is expensive from the viewpoint of reducing construction costs when creating a wide variety of reed fields. The inventor thought. We thought that it was necessary to examine the soil used so that construction costs could be actively reduced without using horticultural soil.

  Conventionally, it has been pointed out that bottom mud containing a large amount of sulfides is difficult to grow because the rhizosphere of the reed is anaerobic. However, if dredged soil can be used to secure the route, it is extremely advantageous from the viewpoint of construction cost. Therefore, the present inventor considered that it was necessary to examine the use of such clay.

  An object of the present invention is to plant an artificial reed field in the brackish water area by planting the reed so that it will not withstand even the salt content of the brackish water area.

  The present invention is an artificial reed field creation method for artificially forming a reed field in a brackish water area, wherein the ground height of the artificial reed field satisfies the growth limit of reeds in the ground rhizosphere Is set as a condition.

  The salinity of groundwater in the reed rhizosphere may be calculated in consideration of the drying rate of the reed rhizosphere with respect to the tide level in the brackish water area of the planned site.

  The salinity of the groundwater in the reed rhizosphere may be an average over a predetermined period calculated by assuming that the salinity is 0 when it is drained from the tide level of the brackish water area of the planned site.

  The present invention relates to an artificial reed field creation method for artificially constructing a reed field in a brackish water area, and temporarily setting the ground height of the artificial reed field to be created with respect to the tide level of the brackish water area of the planned construction site. A step of calculating a reed rate of reed rhizosphere when an artificial reed field is formed on the planned site, a surface salinity of a brackish water area of the planned rebirth, and the reed From the drying rate determined in the rhizosphere drying rate calculation step, the reed rhizosphere groundwater salinity calculation step for obtaining the groundwater salinity of the reed rhizosphere, and the reed rhizosphere determined in the reed rhizosphere groundwater salinity calculation step The groundwater salinity of the reed rhizosphere during the period when the groundwater level falls from the reed rhizosphere is regarded as 0 from the groundwater salinity of Calculate the groundwater salinity of reed rhizosphere considering the dry rate A salinity calculation step, and the groundwater salinity of the reed rhizosphere considering the drying rate calculated in the reed rate considering reed rhizosphere groundwater salinity calculation step satisfies the growth limit for reed salinity, It is characterized by setting the ground height of the artificial reed field planned to be created.

  In addition, PSU described in this specification is a unit of salinity called a salinity practical unit (Practical Salinity Unit). For example, 30 PSU indicates that 30 g of salt is dissolved in 1 kg of seawater.

  According to the present invention, even in brackish water areas where the salinity of the surface layer is low, the influence of salinity on the reed rhizosphere can be reduced and the reed can be reliably alive.

  According to the present invention, since the design standard of the optimum ground height for the region of the brackish water is clarified, it is possible to reliably plant the reed even in the low ground height where the reed can grow.

  In the present invention, bottom mud generated by dredging in planting soil can also be used. The bottom mud containing sulfide, the bottom mud with silt / clay with poor water permeability, and the like can be used, and the artificial reed raw material can be created at low cost without using the garden soil.

  According to the present invention, it is possible to create a reed field at the shore of a closed brackish water area, so that water purification of the closed brackish water area can be performed in this reed field.

  In the present invention, it is possible to calculate the groundwater salinity of the reed rhizosphere from the environmental conditions such as the surface salinity and tide level of the brackish water area of the planned construction site, so that the ground height can be set, so the growth limit of reeds due to the surface layer salinity is evaluated. Unlike conventional methods, it is possible to create an appropriate artificial reed field.

  In the present invention, it is possible to set the ground height according to the salinity decrease amount of the groundwater of the Yoshihara root area with respect to the salinity of the surface layer of the brackish water area, and the salinity situation of the groundwater of the reed rhizosphere considering the drought inundation. Therefore, it is possible to artificially construct the reed field even in the brackish water area of the high salinity surface layer, which was considered impossible to grow from the conventional growth limit evaluation of reed based on the surface layer salinity.

It is a perspective view which shows the creation condition of the artificial reed raw field of this invention. It is sectional drawing cut | disconnected by the AA line of the artificial Yoshihara shown in FIG. It is explanatory drawing which shows the setting environment of an experiment area. It is explanatory drawing which shows the outline | summary of a reed planting experiment zone in a tabular form. It is a graph which shows the fluctuation | variation state of the groundwater level of a reed planting experiment zone. It is explanatory drawing which shows the monthly average tide level for every experimental section, the daily average water depth, and the daily average water immersion time in a tabular form. It is a graph which shows the average salinity in reed planting soil pore water. It is explanatory drawing which shows the mode of the average salinity in reed planting soil pore water in a tabular form. It is explanatory drawing which shows the setting condition of the growth amount investigation control zone of the above-ground part of a reed. It is explanatory drawing which shows the condition of the investigation point of the above-ground part of Yoshi in a tabular form. (A), (B) is a graph which shows the growth amount seen from the average number of ground stems and average stem length extension in a control section. (C), (D) is a graph which shows the amount of growth seen from the average number of ground stems and average stem length extension in the experimental section. (A), (B) is a graph which shows the growth amount seen from the above-ground average fresh weight in the control section, and average dry weight. (C), (D) is a graph which shows the growth amount seen from the above-ground average fresh weight and average dry weight in an experimental section. It is explanatory drawing which shows the amount of growth of the rhizome of the reed of an experimental section in a table form. (A) is a graph which shows the average above-ground stem height of a reed, (B) is a graph which shows the average number of reeds. It is explanatory drawing which shows the actual value in a test group and a control group in a table | surface form. It is a perspective view which shows the structure of the artificial reed original in Embodiment 2. FIG. (A), (B) is sectional drawing of the artificial reed field shown in FIG. 16 at the time of using soil with favorable water permeability for planting soil. (A), (B) is sectional drawing of the artificial reed raw field shown in FIG. 16 at the time of using the soil where water permeability is not favorable for planting soil. It is a perspective view of the artificial reed original of the structure which provided the drainage channel shown in Embodiment 3. FIG. (A), (B) is sectional drawing of the artificial reed original shown in FIG. (A), (B), (C) shows the modification of a drainage channel, respectively. (A) is a perspective view of the artificial reed original formed in the floating island state shown in Embodiment 4, (B) is sectional drawing. It is explanatory drawing which shows the condition of the salinity measurement of the pore water of planting soil. It is a graph which shows the correlation with a salinity fall amount and monthly average drying rate x monthly precipitation. It is a graph which shows the salinity monthly average value of 20 cm of groundwater below the surface of the earth. It is a graph which shows the production amount of a reed ground part. It is a graph which shows the monthly average drying rate of the natural reed root area. It is a correlation diagram which shows the relationship between a rhizosphere drying rate and reed production. It is a graph which shows the calculation result of the salinity of the apparent ground surface 20cm below (the drying rate consideration reed rhizosphere groundwater salinity). It is a graph which shows the actual value which measured the groundwater salinity 20cm below the surface surface in August when the drying rate of reed rhizosphere is not considered. It is a graph which shows the actual value which measured the groundwater salinity of 20 cm below the surface surface in September when the drying rate of reed rhizosphere is not considered.

(Embodiment 1)
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a perspective view showing a state of creation of an artificial reed base according to the present invention. FIG. 2 is a cross-sectional view showing a state cut along line AA in FIG.

  In the case shown in FIG. 1, an artificial reed field B is provided with a concrete revetment 10 at the water's edge in a brackish water area A such as a brackish lake. As shown in FIG. 1, the artificial reed field B is constructed such that a water-permeable bank 11 is built in a substantially U-shape in front of a predetermined range along the concrete revetment 10, and planting soil 12 is provided inside. Yes. In the case illustrated in FIG. 1, the bank 11 is configured as a sarcophagus 11a.

  The sarcophagus 11a (11) is a waterfront on the concrete revetment 10 side of the brackish water area A, that is, a point that is constructed from the construction position of the concrete revetment 10 toward the offshore side of the brackish water area A and proceeds to the offshore side of the predetermined distance. Thus, it is constructed toward the concrete revetment 10 at a point constructed along the concrete revetment 10 and constructed to a predetermined length, and is constructed so as to be substantially U-shaped when viewed from above.

  As shown in FIG. 2, the sarcophagus 11 a may be constructed by stacking the rubble 13 along a bottom surface 14, which is an original ground that gradually becomes deeper in the brackish water area A, so that the central part is raised in a mountain shape. By using the sarcophagus 11a built with the rubble 13 as the bank 11, water passes through the gaps between the piled rubble 13, and the water permeability of the bank 11 can be secured. What is necessary is just to set the height of the center part of the sarcophagus 11a according to the ground level of the planting soil 12. FIG.

  As shown in the cross-sectional view of FIG. 2, a soil runoff prevention layer 15 is constructed on the inner side of the sarcophagus 11a with a predetermined thickness along the inner surface of the sarcophagus 11a. The soil runoff prevention layer 15 may be constructed by stacking sandbags filled with sand or crushed stone, for example. The height of the soil runoff prevention layer 15 having such a configuration is constructed in accordance with the height of the planting soil 12.

  Erosion due to waves of the planted soil 12 is prevented by the bank 11 formed in the sarcophagus 11a. In addition, water permeability is ensured by water going back and forth between the outside and inside of the sarcophagus 11a from the gap of the rubble 13 constituting the sarcophagus 11a. If the surface of the planting soil 12 is submerged and then accumulates in a state where the water is drawn, the salinity of the planting soil is concentrated and increased at the time of drying in that state. If water permeability is given to the water, the water passes through the bank 11 and into the planting soil 12, so that the salinity can be prevented from becoming high.

  The soil runoff prevention layer 15 provided inside the bank 11 can more effectively prevent the planted soil 12 from running away. In addition, as long as it is a structure which can ensure the water permeability of the bank 11, structures other than the sarcophagus 11a of the said structure may be sufficient. By configuring the bank 11 other than the sarcophagus 11a, it is possible to ensure sufficient water permeability and provide the soil runoff prevention function, so that the configuration of the soil runoff prevention layer 15 described above is not provided. It doesn't matter. This configuration will be described in detail in a fourth embodiment described later.

  Planted soil 12 is placed in a range surrounded by a stone wall 11a provided with a soil runoff prevention layer 15 on the inside. As shown in FIG. 2, the planting soil 12 includes a planting floor soil 12 a and a planting floor soil 12 b. As the planted floor soil 12a, soil having good water permeability such as gravel, crushed stone, and sandy soil may be used. Thus, by ensuring water permeability, the water of the brackish water area A that passes through the sarcophagus 11a can be further made to enter the planting soil 12 to purify the water that has passed therethrough.

  Moreover, by making the water permeability of the reed planting floor soil 12a good, the water permeability of the reed planting floor soil 12b can also be made good, and the area around the root of reed C is aerobic. It is also possible to improve the development of reed rhizomes.

  In this way, it is preferable to use soil having good water permeability for the planting floor soil 12a in order to ensure the water permeability of the planting floor soil 12b. If the soil which can fully secure the water permeability required for the development of can be used, the soil under the planting floor 12a may be a soil with low water permeability or no water permeability.

  The bank 11 has a gentle and gentle slope toward the outside of the Yoshihara. This is to make it easier for organisms such as fish such as goby, shellfish such as sea crabs, shellfish such as kingfisher, etc. to enter the reed field from around the reed field. By ensuring the entrance of such benthic organisms, the biological environment found in natural reed fields can be restored. A rich ecosystem can be reproduced not only by purifying water but also by restoring the natural biological environment. If a large step is provided inside and outside the bank, such creatures cannot enter.

  The planted underfloor soil 12a is fed along the bottom surface 14 of the brackish water area A so that the depth of the planted floor soil 12b from the ground surface 12c becomes flat at a level lower by 25 cm or more. The planted floor soil 12b is put flat on the planted underfloor soil 12a that has been thrown flat in this way so that the ground height is higher than the average tide level.

The planting floor soil 12b is provided in a depth range of 25 cm or more from the ground surface 12c, and the soil in which the growth of the underground stems of the reed C is promoted may be introduced as a guest soil. As the customer soil, for example, construction residual soil, dredged soil that is dredged for securing the waterway of the brackish lake, and the like can be used. The soil quality of the soil used as the planting floor soil 12b is preferably, for example, sandy soil, sandy mud soil containing silt or clay, or sandy soil mixed with pebbles and having good water permeability. The water permeability is desirably at least 1 × 10 ⁻⁴ cm / s.

  Gravel that does not contain sand and soil quality of approximately 100% clay is not preferable. Gravel that does not contain sand is not preferable because the soil porosity increases and the reed tends to become unstable even if the root grows. In almost viscous clay such as clay, the soil in the rhizosphere of the reed stem of Yoshi C, which does not have water permeability and requires an aerobic environment, is used. Since it hardens, it not only slows the development of the rhizome, but may cause root rot in some cases, and its use is not preferred.

  Furthermore, when the salinity of the brackish water area A is high, for example, the salinity of the surface layer is 14 PSU in the salinity practical unit, and when it is higher than this standard value, the ground height is set, for example, April of the brackish water area A. It is preferable to set higher than the monthly average tide level for 5 months from April to August. If this ground height is set, the growth of reed C is expected, that is, the period from April to August when the growth rate is high, affects the growth of reed based on brackish water entering the planting floor soil 12b. The influence of salinity can be minimized.

  In the above configuration, the monthly average tide level was used as the standard for setting the ground height as the average tide level, but it is not necessary to limit the period for calculating the average to the moon, and a period during which the average tide level can be calculated according to local conditions is set. It doesn't matter.

  Such an average tide level is a value obtained for setting a standard for how much the ground height should be set in order to suppress the influence of the salinity on the growth of reed as much as possible. Therefore, the average tide level needs to be within a period in which the trend of the tide level of the reed's aboveground stem can be shown.

  In the above description, the reason why the monthly average tide level for five months from April to August is that the long-term growth of reeds in Japan is from April to August. By suppressing the influence of the salinity during this period, it is possible to avoid the inhibition of reed growth as much as possible.

  Therefore, depending on the geographical situation of the place where the artificial reed field is created, such as whether it is a cold region environment, a warm environment, a domestic environment, a foreign environment, or even the type of reed, such an average The period for calculating the tide level can vary, and strictly speaking, it may be set according to individual conditions.

  Depending on the creation area or the type of reed, the lifetime may vary. For example, the period may be shorter than the period range from April to August, or may be longer. There may be a case where the period does not overlap the above-mentioned period range at all. In short, it is only necessary to fully understand the longevity of reeds in the planned site and to obtain the average tide level within that period.

  By the way, the period from April to August is the case where reeds (Phragmites communis) are planted. In Japan, if it is within this period, it is sufficient to estimate the longevity of reeds that grow naturally. It is considered a period.

  However, when the low salinity part of the surface layer of brackish water area A is formed to a deep water depth, the monthly average salinity of the surface layer from April to around August is a salinity practical unit of 14 PSU or less. If it is set to be below the lower surface of the soil 12, the ground height can be set lower accordingly.

  As the surface layer of the brackish water area, for example, it may be equal to the planting soil thickness, and a range of 0 to 0.25 m may be assumed. As the average salinity of the surface layer, the monthly average salinity was used as a reference for setting the ground height. However, as described in the explanation of the average tide level, it is not necessary to limit the average to the monthly average salinity. The surface layer range should be set according to the local brackish water situation, and the period when the average salinity can be grasped should be set. Furthermore, it is needless to say that the average salinity calculation period should be calculated so that the average salinity of the reed can be obtained in the same manner as the above-described explanation regarding the calculation of the average tide level.

  With regard to the point that the salinity should be 14 PSU in terms of the salinity practical unit, it is preferable that the salinity is lower for the growth of reeds. It is important in creating the field. Experiments show that sufficiently good reed growth can be seen with 14 PSU. 14 PSU or less means that it may be 0 or a value close to 0. In such a case, it will lead to the creation of an artificial reed field in fresh water.

  Conventionally, the relationship between the salinity of the surface layer of such brackish water and the ground height of the reed planting soil has not been clarified, and has been clarified for the first time by the present inventors. Thereby, even in brackish water areas, the reed field can be artificially created without being hindered by salt.

  It is necessary to pay attention so that the ground surface of the planting floor soil 12b is formed as flat as possible and does not form a large uneven portion. This is to prevent a puddle of brackish water on the ground surface as much as possible. This is because when the puddle is formed, the salinity of the puddle is concentrated at the time of drying, which may affect the growth of reed C, and this effect is eliminated as much as possible.

  The effectiveness regarding the reed growth of the artificial reed original land of the present invention having such a configuration was verified by the following experiment. In the verification, an experimental area was set up in an actual brackish lake.

  As shown in Fig. 3, the experiment was set up as a reed planting experiment zone near the north of the tidal flat deposited at the mouth of the Imagawa River off the riverfront of Chibada, Kosai City. Within the tidal flat between the Imagawa and Maekawa waterways, it is set to a range of 50m to the east and 30m from the north to the north.

The experimental group set in such a range has an outline as shown in Table 1 shown in FIG. The experimental plot was divided into A to D, and the floor shape of the planting soil in which reeds were planted was formed into a circular trapezoid with an embankment height of 0.5 m and a diameter of 5 m. The soil composition consists of soil X with a gravel with a low silt and clay content and a permeability of 10 ^-3 cm / sec or more, and a soil with a silty and clay content with a permeability of 10 ^-5 cm / sec or less. Y.

  Soil X was used for experimental sections A and C, and soil Y was used for experimental sections B and D. Furthermore, in order to see the effect of ground height, the height of the reed planting floor soil is set to TP. + 0.15m in the experimental sections A and B, and set to TP. 0.00m in the experimental sections C and D. did. Note that TP. Is an abbreviation for Tokyo Peil and indicates the average sea level of Tokyo Bay.

  In addition, in order to compare the effectiveness of the situation in the experimental zones A to D with the natural reed field, a control zone E was established in the brackish water area of the site. In Control Zone E, the reed floor shape was left as it was. The soil composition was sandy soil in the original topography, and the ground height was confirmed to be about the same as TP.

(Experiment 1)
In this experiment, the growth environment of reeds in the experimental groups A to D and the control group E having such a configuration was examined. The changes in groundwater level of reed planting soil in reed growth environment were compared. The result is shown in the graph of FIG. In the figure, there is a missing part of the graph in the middle, but this is the part where the tide level is higher than the ground level, and the fluctuation of the groundwater level is not required.

  In the graph of FIG. 5, the vertical axis represents the groundwater level, and the horizontal axis represents the measurement date and time. It can be determined that the greater the difference in the vertical height of the groundwater level, the greater the permeation thickness that indicates the amount of water entering and exiting. From FIG. 5, the natural reed field where reed roots developed in sandy soil has a large water permeability, and the water permeability of experimental sections A and C mainly composed of sandy soil is large. On the other hand, in the experimental fields B and D of Yoshihara, which was constructed from soil with a lot of silt and clay, the change in groundwater level was poor and the water permeability was small.

  That is, from the graph of FIG. 5, it can be seen that the amount of water entering and leaving the reed planting soil is large in the natural reed field in the control section E, the experimental sections A and C, and then in the experimental sections B and D.

(Experiment 2)
In this experiment, we investigated the submergence time of reed planting floor soil. The survey results of monthly average tide level, daily average water depth, and daily average submergence time are shown in Table-2 in FIG. From Table-2, it is clearly understood that the submergence time of reed planting floor soil varies depending on the ground height of reed planting floor soil.

  In the experimental areas A and B, which have higher ground, the average tide level was lower than the ground level until September, when reed growth was expected, and the average tide level was higher than the ground level only in October. That is, it was dried out on average. The average tide level from June to September was 0 to 20 cm deep from the surface of the earth, corresponding to the height of the planted reed root.

  Therefore, it is considered that the development of rhizomes was influenced by the fact that the low salinity of the brackish water surface layer was located at the soil depth in the rhizosphere of reed root during these periods when rainfall was expected. That is, it can be seen that the salt content in the reed growth environment is lower in the experimental groups A and B than in the experimental groups C and D and the control group E.

  On the other hand, the monthly average of submergence time is 10 hours or less until September, and the average tide level rises the most in the year and in addition to October, when abnormal tide level was recorded, 12 hours after November. It was the following. That is, it has a low salinity and a short submergence time.

  In the experimental sections C and D having the lower ground, it can be seen that the average tide level is higher than the ground height from July to November, and lower than the ground height in other months. In other words, until September when the reed grew, the average tide level was higher than the ground level, and the daily average submerged time was 10 to 15 hours. That is, it can be said that the salinity in the reed growth environment is an environment that is exposed to high salinity for a long time as compared with the experimental sections A and B.

  In the control area E, as in the experimental areas C and D, the average tide level was higher than the ground height from July to November.

(Experiment 3)
In this experiment, the salinity in the soil pore water was verified. A part of the continuous salinity measurement data of reed planting floor soil pore water is shown in FIG. In the salinity measurement, an observation hole was drilled at a predetermined depth from the planting soil surface, and the salinity in water in the hole was measured. The data shown in FIG. 7 is a value measured in September.

  In the figure, a missing part in the middle is a part that could not be measured due to maintenance of the measuring instrument. When comparing the experimental sections having the same soil composition, it can be seen that the experimental sections A and B having a relatively high ground height have lower soil pore water salinity than the experimental sections C and D having a lower ground height.

  The results are shown in Table 3 in FIG. From the results of monthly average values of practical salinity of soil interstitial water, it is 13.1 to 13.3 PSU or less from June to August in the experimental zones A and B where the ground height is high. Also, it was about 20 PSU or less.

  On the other hand, in the experimental sections C and D having a low ground level, they were 16.8 PSU and 19.6 PSU in August, respectively, and 22.2 PSU and 24.8 PSU in September, respectively.

  That is, in comparison with the experimental sections A and C created with the soil X, it can be seen that the experimental section A has lower practical salt content. It can be seen that, in the average value for 8 months from June to January of the following year, the experimental section A is lower than the 4.6 PSU experimental section C. Similarly, in comparison with the experimental sections B and D created with the soil Y, it can be seen that the experimental section B is 3.1 PSU lower than the experimental section D.

  In September, November, December, and January, the salinity in the pore water of the planting floor soil was the salinity practical unit, despite the fact that the height of the experimental zones A and B was higher than the monthly average tide level. It is higher than 14 PSU. This is thought to be because there was little rainfall at this time and salinity rose to the surface layer of the experimental area, and the brackish water area was not formed.

  From the above results, it was found that there was a difference in salinity in the soil pore water due to the difference in the ground height of the reed planting floor soil. That is, it can be seen that the amount of salinity in the reed planting floor soil can be reduced depending on the setting of the height of the ground, and the state of salinity suitable for reed growth in brackish water can be set.

  In addition, the influence of the ground height is greater than the influence of the difference in water permeability. Soil pore water between the experimental sections A and B and the experimental sections C and D, which are constructed at the same ground height and have different planting floor soils. It is clear from the comparison between the salinity difference of the soil and the salinity difference of the soil pore water in the experimental sections with different ground heights.

  According to the above experiments 1 to 3, the experimental section A having a high ground height in the soil X has a larger water permeability than the experimental sections C and D, and the average tide level until around September when reed growth is expected. It was confirmed that the ground height was high, the monthly average submergence time was short, and the salinity of the soil pore water was low.

(Experiment 4)
In this experiment, the growth amounts of reeds in the experimental groups A to D and the control group were compared. In addition, as a control group provided for comparison with the experimental group, as shown in Table 4 of FIGS. 9 and 10, an X ₁ -X ₁ line, an X ₂ -X ₂ line, a Y ₁ -Y ₁ line, Four locations from the control zone 1 to the control zone 4 were set on the side of the experimental zone surrounded by the Y ₂ -Y ₂ line close to the Imagawa river, based on the ground height and the positional relationship with the river.

Confirmation of the growth of reeds is as follows: average number of reeds (lines / m ² ), average stem length (m / m ² ), average fresh weight (kg / m ² ) measured on site immediately after cutting, after cutting It investigated from the viewpoint of the average dry weight (kg / m < ² >) measured by drying at 105 degreeC. In addition, about the experimental group, all the reeds in the experimental group were cut and evaluated by the average value per planted plant. Moreover, about the control plot, the reed within the frame of 50x50cm was cut, and it evaluated by the average value per unit area.

  First, the situation in the natural reed field (control zone) was investigated. The results are shown in FIG. 11 (A), (B), FIG. 12 (A), (B), except for the average number shown in FIG. (4) It turns out that all are favorable.

  Since the upper reaches of Imagawa are freshwater reed fields and the control areas are all reed fields in brackish waters, it is clear that freshwater reed fields grow better than reed fields in brackish waters. Moreover, in the control plots 1-4, it turns out that the growth in the control plot 2 is favorable. This is thought to be due to the low ground height and the long contact time with the river water flowing in from the Imagawa River.

  In addition, control zone 3 is located in Imagawa rather than control zone 2, but since the ground height is higher than control zone 2, the contact time with the influent water of Imagawa is short and the amount of growth is considered to be smaller than control zone 2. It is done.

  In other words, the results of the control plot showed that the growth density of the reed, the stem length of the ground stem, and the yield (dry weight) were the best in the area where the river water of Imagawa directly flowed in. It was confirmed that salinity affected.

  Next, the amount of reed growth in the experimental groups A to D was compared from the same viewpoint as the observation viewpoint of the control group.

  When reed was planted, the ground height of the reed planting floor soil was confirmed to affect growth. In the experimental sections A and B in which the ground height was set high, the growth situation was good in both the above-ground part and the underground part (underground stem). On the other hand, in the experimental sections C and D in which the ground height was set low, the growth situation was not good in both the above-ground part and the underground part (underground stem), and the growth of the underground stem was particularly poor.

  That is, from the results of FIGS. 11C, 11D, 12C, and 12D, it can be seen that when the experimental sections are arranged in descending order of the amount of growth, the order of A> B> C> D is satisfied. That is, it can be seen that the amount of growth increases in ascending order of the influence of salinity in the reed environment. Such a result was convincing from the consideration that salinity becomes a growth inhibiting factor for the growth of reeds obtained in the control group.

  When reed was planted, it was confirmed that there was a difference in the final production of the above-ground part due to the difference in soil quality. The experimental sections A and C (silt / clay content 2 to 4% by weight) with less silt / clay content are higher than the experimental groups B and D (silt / clay content 18 to 21%) with higher silt / clay content. It was confirmed that it was 2 to 1.5 times more.

  As for the rhizomes, the number of plants per strain was higher in the experimental sections A and C with less silt / clay, compared with the experimental sections B and D, respectively, but no significant difference was observed. .

  Such a situation can also be confirmed from Table-5 shown in FIG. In Table-5, the reed grows several rhizomes from one strain. Therefore, three strains were dug in each experimental area, and the growth status was confirmed. The earth covering corresponds to the depth from the ground surface to the upper surface of the rhizome. For each strain, the stem length from the strain and the distance from the center of the strain to the stem tip were measured.

  The soil depth at which the rhizome of the planted reeds developed was 8 to 13 cm on average from the surface, and 23 cm in the experimental zone B at the maximum. In the control plot (natural reed field), the results of the soil core sample survey confirmed that the reed stems were within a range of about 20 cm from the ground surface.

  Although the rhizomes developed after planting from the reed strains were growing while diverging in the soil, there were few that diverged from the rhizomes and grew on the ground stems. The growth of reeds planted in the first year is thought to be the development of the aerial parts (stems, leaves, ears) from the planted plant and the extension of the branch of the underground stem in the first year. Therefore, it is considered that the branching of the rhizome between the planted strains and the growth of the above-ground part will be after the next year of planting due to the developmental state of the rhizome.

  The following year after planting, the growth of reeds was observed in each of the experimental sections A, B, C, and D. In the experimental sections A and B where the ground height was high, reed growth was observed, but in the experimental sections C and D, most strains did not grow. Such growth conditions are shown in FIGS. 14 (A) and 14 (B). FIG. 14A shows the average ground stem height per area, and FIG. 14B shows the average number of stems per area. In addition, the ground stem height and the number were selected for each 5 strains of the average strain near the center of each experimental section, and the ground stem height and number within a 50 × 50 cm frame were measured every 3 months. .

  As is clear from FIGS. 14 (A) and 14 (B), experimental sections A and B with a high ground height have a larger number of growing plants and a larger stem height than experimental sections C and D with a low ground height. Is confirmed. This result is considered that the experimental sections C and D having a low ground height were more damaged by salinity because the submergence time with respect to the tides was longer than the experimental sections A and B.

  14A and 14B, it was confirmed that the growth in the experimental group A was better than that in the experimental group B. Therefore, as a result of observing the fluctuation of the groundwater level during the experimental period shown in FIG. 14 in the same manner as shown in FIG. 5, in the experimental section B formed with soil having a high silt / viscosity component, the permeation thickness, that is, the groundwater It was found that the fluctuation range of the position was less than 5 cm.

  Therefore, by considering both the result shown in FIG. 14 and the result of the fluctuation of the groundwater level, the fluctuation width of the groundwater level due to the fluctuation of the tide, that is, the fluctuation width of the groundwater level from the surface of the tide is 5 cm below the ground surface. It has been confirmed that it is preferable to configure to be performed up to a deep depth range.

In addition, the experimental plots A, B, C, D and the control plot E were initially set as shown in Table 1 shown in FIG. 4, but then the details of the soil conditions and the like were shown as shown in Table 6 of FIG. Actually measured. From the results of Table 6, regarding the particle size (%) of the planted soil, gravel content having an average particle size of less than 75 mm and 2 mm or more, sand content having an average particle size of less than 2 mm and 75 μm or more, and an average particle size of less than 75 μm The mixing ratios of silt and clay were measured. In addition, the hydraulic conductivity (cm / sec), wet density (g / cm ³ ), dry density (g / cm ³ ), and ground height (TP.m) were also measured.

Based on the above results including Table 6 shown in FIG. 15, and based on the conditions of experimental plot A and control plot E where the best growth of artificially planted reeds was confirmed, planting It is understood that the soil is preferably formed of soil having a hydraulic conductivity of 1 × 10 ⁻⁴ cm / s at a depth of 25 cm below the surface in consideration of the depth at which the rhizomes of reeds develop.

In addition, from the results of soils with poor water permeability, such as experimental plots B and D, the hydraulic conductivity is 1 × 10 ⁻⁶ to 1 × 10 ⁻⁴ cm / s up to a depth of 25 cm below the ground surface as planting soil. If the soil is planted with soil, the drainage layer and / or drainage channel that causes the groundwater level to fluctuate to a depth deeper than 5 cm below the surface of the soil will be provided to reduce the influence of salinity due to tidal fluctuations. Complementary treatment is necessary to

  Through the above series of experiments, it is possible to obtain the standard of the growth conditions of the reed when artificially constructing the reed field in a brackish lake like Lake Hamana, and based on this, the artificial reed field of the present invention and the method of constructing the reed field Is configured.

(Embodiment 2)
In this Embodiment 2, the structure of the artificial reed field which can be proposed when the soil with good water permeability is used as the planting soil as described above, and the artificial reed which can be proposed when soil with poor water permeability is used. Each of the original configurations will be described.

When soil having a hydraulic conductivity of 1 × 10 ⁻⁴ cm / s or more is used as planting soil as described above, an artificial reed field B can be configured as shown in FIGS. The configuration shown in FIG. 16 is formed by surrounding the concrete revetment 10 behind the concrete revetment 10 in a substantially U-shape with the bank 11. In the following description, the same reference numerals are used for the same reference numerals as those shown in FIGS.

  The bank 11 may be configured by stacking rubble stones 13 into a stone wall 11a. Inside the sarcophagus 11a, a sandbag filled with sand or a soil runoff prevention layer 15 in which crushed stones are stacked is provided. Planted soil 12 that satisfies the hydraulic conductivity is placed inside the soil runoff prevention layer 15 thus formed. As shown in the cross-sectional view of FIG. 17 (A), a base 20 is provided so that the upper surface becomes flat along the bottom surface 14 which is the original ground that gradually becomes deeper from the concrete revetment 10 to the brackish water area A, and on that. Planting soil 12 is contained.

  The base 20 may be formed on the planting floor soil 12a similar to that shown in the first embodiment, or may be formed in other configurations. In the case shown in FIGS. 16 and 17, since the water-permeable soil having a large hydraulic conductivity is used for the planting soil 12, groundwater is excluded at the time of lower tide, and the groundwater level is 5 cm or more from the ground surface of the reed floor. Can be reduced, and salt damage can be reduced.

Next, when soil having a hydraulic conductivity of 1 × 10 ⁻⁶ to 1 × 10 ⁻⁴ cm / s is used for the planting soil 12, the planting soil 12 has a depth deeper than 5 cm below the ground surface. Complementary measures are required to provide a drainable layer that can cause fluctuations in the groundwater level and reduce the influence of salinity due to tidal fluctuations.

  In the case shown in FIG. 18, the base 20 having the configuration shown in FIG. 17 is replaced with a drainage layer 21. Since the water permeability of the planting soil 12 is not good, by providing a drainage layer 21 under the planting soil 12, groundwater is eliminated from the drainage layer 21 provided under the planting soil 12 during the tide, The groundwater level is lowered by 5 cm or more from the ground surface 12 c of a certain planting soil 12.

  The drainage layer 21 may use drainage material with good water permeability such as gravel, crushed stone, or coarse sand. Even if the particle size of the drainage material is large, the loss of the planted soil 12 provided on the drainage layer 21 is blocked by the soil loss prevention layer 15.

  The drainage layer 21 is configured by replacing the planting underfloor soil 12a in FIG. 2 of the first embodiment with the drainage layer 21 and the planting floor soil 12b with soil having the above hydraulic conductivity.

(Embodiment 3)
In the third embodiment, when soil having poor water permeability with a hydraulic conductivity of 1 × 10 ⁻⁶ to 1 × 10 ⁻⁴ cm / s is used for the planting soil 12, the planted soil 12 is drained. A configuration in which the path 22 is provided will be described.

  As shown in FIG. 19, the artificial reed field B is formed with the concrete revetment 10 as the back, as shown in FIG. A drainage groove 22 a is provided as a drainage channel 22 on the planting soil 12 surface. For example, a plurality of drain grooves 22a (22) may be provided in parallel at intervals of 1 to 3 m. In addition, as shown in FIG. 19, the laying direction of the drain grooves 22a may not be a plurality of parallel, for example, a plurality of drain grooves 22a may be provided so as to intersect in a lattice shape. I do not care.

  In the configuration in which such drainage grooves 22a are provided, the drainage layer 21 may not be provided under the planting soil 12, as shown in the cross-sectional view of FIG. Since the drainage of the planting soil 12 is sufficiently ensured by the drainage grooves 22a, a configuration as shown in FIG. 17 using soil having good water permeability as the planting soil 12 can be employed.

  Moreover, what is necessary is just to comprise the drainage groove 22a so that it may have the depth united with the layer thickness of the planting soil 12, for example, as shown to sectional drawing of FIG.20 (B). Furthermore, the tip of the drainage groove 22a may be abutted against the soil runoff prevention layer 15 as it is.

  The cross-sectional shape of the drainage groove 22a may be a square cross section as shown in FIG. 20, or an inverted trapezoidal cross section as shown in FIG. In short, any shape that contributes to the improvement of drainage of the planting soil may be used.

  The drainage channel 22 may have a configuration other than the drainage groove 22a. For example, as shown in FIG. 21 (B), drainage material 23 such as gravel, crushed stone, or coarse sand may be filled in drainage grooves 22a laid in planting soil 12. When the drainage material 23 is rough and there is a concern that the surrounding planting soil 12 may flow out between the eyes of the drainage material 23, the periphery of the drainage material 23 is as shown in FIG. What is necessary is just to wrap with the suction | inhalation prevention material 24, such as a net or a water-permeable film. Alternatively, the sandbags may be filled with the drainage material 23 and filled in the drainage grooves 22a.

  As a modified example of the drainage channel 22, for example, as shown in FIG. 21C, a perforated tube 22 b provided with a plurality of through holes around the tube wall in the drainage groove 22 a is filled with the drainage material 23. It is good also as a structure.

(Embodiment 4)
In the above embodiment, the case where the permeable bank 11 and the soil runoff prevention layer 15 in the bank 11 are respectively provided and the planting soil 12 is put inside is described. The case where the artificial reed field is formed in a floating island shape at an arbitrary position of the brackish lake away from the shore will be described.

  As shown in FIGS. 22 (A) and 22 (B), the artificial reed field B of the present embodiment is provided in the brackish lake in a separated manner. Each artificial reed field B is configured such that the planting soil 12 is put in the surrounding area surrounded by the soil runoff prevention bank 25. The soil runoff prevention bank 25 is configured by filling a water-permeable container with a water-permeable drainage material 23 such as gravel, crushed stone, and sandy soil.

  In the case shown in FIG. 22, a sandbag 25a (25) was used as a water permeable container. The drainage material is packed in the sandbag 25 and arranged in an annular shape so as not to open a gap between each other, so that a water-permeable soil runoff prevention bank 25 is formed. The planting soil 12 is placed in a range surrounded by the soil runoff prevention bank 25.

As the planting soil 12, for example, a soil having a hydraulic conductivity of 1 × 10 ⁻⁴ cm / s or more may be used as described above. Further, a base 20 may be provided under the planting soil 12 so as to support the planting soil 12 having a layer thickness of at least 25 cm, which is the depth of growth of reed rhizomes. In such a configuration, the base 20 may be a concrete board or a hardly water-permeable soil. Thus, in the embodiment of the present invention, an artificial reed field can be constructed in a floating island state.

  In addition, what is necessary is just to perform the salinity measurement of the pore water of the planting soil in the artificial reed field B formed in the floating island state similarly to the experiment 3 of the said Embodiment 1, as shown in FIG. That is, a vinyl chloride tube is passed through the planting soil 12 as the observation hole 31. The portion embedded in the planting soil 12 of the vinyl chloride tube is configured in a perforated portion 31a having a plurality of holes around the tube wall, and a salinity sensor 32 is provided in the tube of the perforated portion 31a. deep. With the salinity sensor 32 in the observation hole 31 having such a configuration, the salinity state in the pore water of the planted soil 12 can be observed in real time.

(Embodiment 5)
As can be seen from the first to fourth embodiments, it was confirmed that the ground height of the artificial reed field is extremely important in order to suppress salt damage as much as possible when the artificial reed field is created. Therefore, in the present embodiment, a method for systematically setting the ground height is proposed.

  Regarding the reed growth environment in salt marshes in brackish waters, S. By Ranwell et al. Ecol. , 52, 627-642 (1964), when the submerged water is submerged, the salinity of the surface of the brackish water is 12 PSU, and the growth of reeds is attenuated, 13.5 PSU is the growth limit, and 7 is always flooded. .6 PSU is reported to be the growth limit. In addition, in the Port Technology Research Institute experiment, it has been reported that the salinity of the surface layer of brackish water is 10 PSU or more, which affects the growth, and 20 PSU is the limit.

  Thus, the influence of salinity on reed that has been reported in the past has been evaluated based on the salinity of the surface layer of the brackish water area. The surface salinity is investigated, and it is determined whether or not the conditions are met.

  However, as is clear from the description through the first to fourth embodiments, the influence of salinity on the growth of reeds through experiments of the present inventors is important for the salinity of groundwater in the rhizosphere of planted reeds. It turns out that it becomes a judgment index. That is, it is necessary to judge the growth environment of the reed field based on the level of salinity in the groundwater of the reed rhizosphere, and it cannot be sufficiently evaluated by the size of the surface layer salinity in the brackish water area described in the above-mentioned conventional report.

  In this regard, the salinity of the surface of the lake water and the salinity of the groundwater of the reed rhizosphere are different, and the above report shows that even in the high salinity waters of the salinity of the surface that seems to exceed the growth limit of reed. It is to be confirmed through the fact that good reed growth is seen.

  From this knowledge, the present inventor cannot sufficiently evaluate the growth environment of reeds with the evaluation method based on the surface layer salinity of brackish water based on the above-mentioned conventional report for the creation of artificial reed raw. We thought that it was not possible to establish a proper artificial reed field construction procedure.

  Furthermore, the growth of reeds is carried out by taking various nutrients with water from the rhizosphere, and the growth of the rhizomes, branching and growth, so that the reeds grow in salt. The present inventor considered that the influence exerted depends on the salinity of the groundwater in the reed rhizosphere. However, in the above-mentioned conventional literature, there is no clear recognition that the salinity situation in the reed rhizosphere has a significant effect on salinity damage, and the growth limit of reed as judged from the surface salinity of brackish water is reported Only.

  In addition, in the case of a brackish water area where the reed field is affected by salinity, the inventor of the present invention changes the tide level due to the tide, and the reed root area is submerged in accordance with the change. I thought that it would be necessary to consider such submergence in the salinity of groundwater. There is no previous report on how much the reed rate in the reed rhizosphere affects reed growth, and we thought that it was necessary to establish a new consideration for the creation procedure.

  Thus, in the conventional creation method based on the salinity of the surface of the lake water, it is impossible to accurately determine the ground height in the creation of the artificial reed field in the brackish water area. Therefore, the present inventor newly proposed a method for setting the ground height in consideration of both salinity in the rhizosphere of the reed field, that is, the salinity of groundwater in the reed rhizosphere and the drying rate of the reed rhizosphere. did.

  In the artificial reed field creation method of the present invention, the setting of the ground height of the artificial reed field is matched with the situation of the brackish water area of the planned production area, the reed rhizosphere dry rate calculating step, the reed rhizosphere groundwater salinity calculating step, It can be obtained from the respiration rate consideration reed rhizosphere groundwater salinity calculation step.

  In other words, in the recalculation rate calculation process of the reed rhizosphere, the ground height of the artificial reed field to be created is temporarily set for the tide level that fluctuates due to the tide of the brackish water area of the planned recreation area. This is a process for determining the drying rate.

  The drying rate (D:%) can be shown as the average monthly drying rate of the reed rhizosphere, while the tide level fluctuates due to the tide when the reed field is planned. When calculating the monthly average drying rate, it is necessary to investigate the rhizomes of the reed field around the planned site and obtain the actual reed rhizosphere soil depth. From the results of the survey of natural reed fields, 20 cm below the surface should be set as the reed rhizosphere for convenience.

  However, the depth of the soil in the reed rhizosphere varies slightly depending on the location of the reed field. From the results of field surveys, the reed rhizosphere has reached 25 cm below the surface. Depending on the situation, the reed rate may be determined by setting the reed rhizosphere to a depth in the range of 20 to 25 cm.

  The dry rate (D) is calculated from the tide level data as follows. If there is no existing data, tide level data needs to be measured locally. Although it is preferable to obtain yearly data as much as possible, for example, if it is difficult to obtain yearly data, data from the end of March to September, which is the lifetime of reed, may be obtained. Another method is to measure the tide level for at least one month at the site and estimate the annual tide level from the data of the tidal stations near the planned site.

  In addition, the period setting of the above-mentioned late March to about September as a lifetime of reed uses the average reed life of reed in Japan to the last. Naturally, the longevity of reeds is expected to deviate from the above average period due to differences in the actual reproductive environment of reeds. Naturally, it is natural that the setting of the long life can be changed as appropriate.

  Regarding the tide level, except for the case where tide level data is obtained directly by continuous measurement, the only available tide level data are both low and high tide levels, time, and average tide level. Therefore, in order to obtain the monthly average drying rate from such data, it is first necessary to calculate the tide level at an arbitrary time.

  For example, the tide level every 10 minutes is calculated, and from the tide level data, the daily drying time (h / day) of the assumed root height of the reed field (for example, 20 cm below the surface as described above) ) And the daily drying rate (%; h / 24h) can be determined from this. By calculating the monthly average of the daily drying rate thus determined, the monthly average drying rate (%) can be determined. In calculating the average drying rate, depending on the situation, it may be possible to adopt an average drying rate during the period when the reed grows, for example, the period from late March to September, even if it is not the monthly average.

  Next, in the reed rhizosphere groundwater salinity calculation step, the reed rate (D) is used to reinforce the reed base in the reclaimed site from the surface salinity of the brackish water area. Find the rhizosphere groundwater salinity.

  The surface layer salinity (A) in the brackish water area of the planned site can be obtained as follows. That is, first, the presence or absence of existing salinity data in the brackish water area is confirmed and used if available. However, if there is no existing data that can be used, it will be measured and obtained locally. It is preferable to obtain yearly data as much as possible. However, if it is difficult to obtain yearly data, data from late March to around September, which is the growing period of reeds, may be obtained.

  On the other hand, the groundwater salinity (B) at the soil depth corresponding to the reed rhizosphere in the case where an artificial reed field is created in the brackish water of the planned site is lower than the surface salinity A of the brackish water. This has been confirmed by the inventors' experiments. This is because the salinity of the groundwater is diluted by infiltration of rainwater into the groundwater and the surface of the brackish water surface by rainwater in response to the intrusion of water in the brackish water with high salinity due to rising tide levels. Conceivable.

  In view of the above relationship between the salinity of the surface layer (A) and the groundwater salinity (B) of the reed rhizosphere, the present inventor has found that the empirical formula ΔS = a (D × R) + b holds. . Here, ΔS is the surface salinity of brackish water (A: PSU indication) of the planned site, and the groundwater salinity (B: PSU indication) of the reed rhizosphere when an artificial reed field is created on the planned site. The salinity reduction amount (PSU) shown as the difference in Such ΔS may be shown as a monthly salinity reduction amount. Incidentally, the relational expression ΔS = A−B is established.

  D is a drying rate calculated in the reed rhizosphere drying rate calculation step. R is the monthly precipitation (mm / month) at the planned site. It can be acquired from weather data. Or it does not matter if it is actually measured locally.

  “a” and “b” are values determined for each brackish water area of the planned construction site, and are obtained using a preliminary survey or data on the reed field of a similar brackish water area. For example, ΔS and D × R values are actually obtained at the planned construction site, a is obtained from the slope of a straight line obtained by plotting ΔS and (D × R), and b is obtained from the intercept. it can.

  For example, FIG. 24 is a graph showing the correlation between the amount of salinity decrease in April to September and the monthly average drying rate × monthly precipitation in the natural reed field investigated at Lake Hamana Matsumigaura. , A = 0.0671, b = 2.1097. Alternatively, if such data is already required in similar brackish waters, it may be used.

  Next, the drying rate (D) determined in the reed rhizosphere dry rate calculating step and the reed root determined in the reed rhizosphere groundwater salinity calculating step From the groundwater salinity (B) of the sphere, the monthly average value of the groundwater salinity (C) of the reed rhizosphere that is more suitable for determining the growth limit of the reed is obtained. Reed rhizosphere groundwater salinity (C), which is more suitable for determining the reed growth limit, is distinguished from reed rhizosphere groundwater salinity indicated by B. I will call it.

  Considering the dry rate, the reed rhizosphere groundwater salinity (C) is assumed to be 0 in the reed rhizosphere groundwater during the period when the reed rhizosphere is dry, that is, during the period when the groundwater level is lower than the reed rhizosphere. The salinity value calculated as follows. The present inventor has found that through the experiment, the consistency of the groundwater salinity condition in the reed rhizosphere and the actual reed growth condition can be explained by making such a 0 look.

  Therefore, it is possible to set an appropriate ground height by determining whether or not the value of the dry rate consideration reed rhizosphere groundwater salinity (C) satisfies the growth limit for reed salinity. B (1−D / 100) = C between the reed rate consideration reed rhizosphere groundwater salinity C (PSU) and the recycle rate D (%) and reed rhizosphere groundwater salinity B (PSU) Relational expressions can be considered.

  On the other hand, when calculating the drying rate D, the ground height (H: TP.m) is determined after various provisional settings. A plurality of values are calculated according to the height. Therefore, the ground height corresponding to the case where the growth limit is satisfied among the plurality of calculated dry rate-considered reed rhizosphere groundwater salins (C) is the appropriate ground height of the artificial reed field to be created.

  In addition, as the respiration rate consideration reed rhizosphere groundwater salinity (C), the average value of the reed life 4 to 9 months is 14 PSU or less as described above through the experiments of the present inventors. It was confirmed that it should be set to. In addition, as a value of reed rate consideration reed rhizosphere groundwater salinity (C), as long as reed can grow, a value larger than 14 PSU may be set. In such a case, the ground height H corresponding to the drying rate D may be obtained by calculating back the drying rate D corresponding to the set value of the root rate salinity (C) in consideration of the drying rate from the above formula. .

  The ground height setting method according to the present invention has been found from the actual demonstration results at Lake Hamana Matsumigaura described below.

  FIG. 25 is a graph showing the salinity monthly average value of rhizosphere groundwater of natural reed field implemented at Lake Hamana Matsumigaura. FIG. 26 shows the amount of reed production per unit area of the natural reed field at each survey point. FIG. 27 is a graph showing the average monthly drying rate of natural reed fields. FIG. 28 shows the correlation between the rhizosphere drying rate and reed production. FIG. 29 is a graph showing the monthly salinity average value of groundwater 20 cm below the apparent ground surface considering the drying rate (same as the drying rate considering reed rhizosphere groundwater salinity). FIGS. 30 and 31 are graphs showing the changes in the groundwater salinity (B) of the reed rhizosphere 20 cm below the surface in August and September, respectively.

  From Fig. 25, the results showed that the reed rhizosphere groundwater salinity (B) was higher than that of the Ishikawa Kawaguchi reed, where the natural reed field on the Toshiki Coast is the limit of growth, but the production per unit area was 26, it can be confirmed from Fig. 26 that there are more natural trees in the Toshikaigan area with higher salinity (B) in the rhizosphere of the reed than in the freshwater area of the Imagawa Kawaguchi.

  On the other hand, from the average monthly drying rate (D) in FIG. 27, it is confirmed that the natural tree reed field on the Toshiki Coast has a significantly higher dry rate (D) than that on the fresh field at Imagawa Kawaguchi. Therefore, the difference in the drying rate (D) is considered to be the reason why the amount of reed production on the Toshiki coast natural reed field with high salinity is higher than that on the fresh water of Imagawa Kawaguchi reed, where the groundwater salinity (B) in the reed rhizosphere is small. It was.

  Therefore, the correlation between the drying rate (D) when assuming 20 cm below the ground surface as the reed rhizosphere and reed production was examined. The result was confirmed to show a good correlation as shown in FIG. The result of FIG. 28 is that, in calculating the drying rate, it is necessary to originally investigate the surrounding rhizosphere of the reed and obtain an appropriate soil depth of the reed rhizosphere. It also means that the assumption that the drying rate (D) can be generally obtained by considering 20 cm below the surface as the reed root zone is effective.

  In addition, when calculating the groundwater salinity in the reed rhizosphere, the drying rate should be fully taken into account, and during the drying period, the salinity concentration of groundwater is assumed to be 0, allowing for a more accurate drying rate. The calculation result of the reed rhizosphere groundwater salinity (C) is shown in FIG.

  The results in Fig. 29 are different from Fig. 25, which shows the dry rate and groundwater salinity (B) of the reed rhizosphere that does not take into account the above-mentioned 0 look-off. It can be seen that in the order of Yoshihara> Toshikaigan natural Yoshihara, the dry rate-considered Yoshi rhizosphere groundwater salinity (C) becomes smaller and agrees with the results shown in FIG.

  From these results, the salinity of groundwater in the reed rhizosphere has a significant effect on the growth of reeds, and the salinity of groundwater in the reed rhizosphere must take into account the drying rate of the reed rhizosphere, It is confirmed that it is preferable to consider the groundwater salinity during the period when the area is dried out as 0. In addition, corresponding to the said FIG. 25, the result of having continuously measured the salinity condition of the groundwater of the reed rhizosphere in August and September is shown in FIG. This result is a graph of measured data, and shows that the reed rhizosphere is dried out during the period when the groundwater salinity (20 cm below the surface) is zero.

  The present invention is not limited to the above-described embodiment, and may be changed as necessary without departing from the scope of the invention.

  For example, in the above experiment, a case where a reed (Phragmites communis) is planted as a reed seed has been described. However, it can be applied to other reeds that grow naturally in Japan. For example, it can be applied to plants belonging to the genus Reed, such as Phragmites japonica, Phragmites Karka, and Phragmites marca. In selecting the species, for example, it is preferable to select and plant a reed that grows in the vicinity of the artificial reed field, in that the ecosystem around the regenerated area can be maintained.

  In addition, for the planted floor soil, it has been explained that it is preferable that the water permeability is good. However, in the configuration of the present invention, the soil quality is particularly limited because the underground stem of the reed is not grown for the soil under the planted floor. Not. For example, it can be used even in clay soil with extremely poor water permeability, for example, 100% sludge. To secure the channel, dredged soil such as bottom mud obtained from the bottom of brackish lake can be used. Since the drying time can be secured by setting the ground height, sulfides in the bottom mud can be diffused at the time of drying, and the influence of sulfides can be mitigated. It becomes. Use of construction soil is advantageous in terms of construction costs.

  In the fourth embodiment, the case where the artificial reed field is configured in the floating island state has been described. However, in the same manner as in the first embodiment, for example, when the artificial reed field is configured with a concrete revetment as a background, Embodiment 4 can be applied.

  Furthermore, it is needless to say that the configurations of the first to third embodiments can be applied to an artificial reed field in a floating island state as in the fourth embodiment.

DESCRIPTION OF SYMBOLS 10 Concrete revetment 11 Dam 12 Planted soil 13 Rubble 14 Bottom 15 Soil runoff prevention layer 20 Base 21 Drainage layer 22 Drainage channel 22a Drainage channel 22b Perforated pipe 23 Drainage material 24 Drainage prevention material 25 Soil runoff prevention bank 25a Sandbag 31 Observation hole 31a Perforated tube

Claims (4)

Artificial reed field creation method that artificially regenerates reed field in brackish water,
A method for generating an artificial reed, characterized in that the ground height of the artificial reed field is set on condition that the salinity of groundwater in a reed rhizosphere satisfies the growth limit of reeds. In the artificial reed original creation method according to claim 1,
The artificial reed creation method, wherein the salinity of groundwater in the reed rhizosphere is calculated in consideration of the drying rate of the reed rhizosphere with respect to the tide level of the brackish water area of the planned formation site. In the artificial reed original creation method according to claim 2,
The salinity of ground water in the reed rhizosphere is an average over a predetermined period of time calculated by assuming that the salinity is 0 when it is drained from the tide level of the brackish water area of the planned development site. Creation method. Artificial reed field creation method that artificially regenerates reed field in brackish water,
Deposition rate of reed rhizosphere when artificial ground is constructed on the planned site by setting the ground height of the artificial reed field to be constructed to the tide level of the brackish water area of the planned site Reed rhizosphere drying rate calculation process,
From the surface salinity of the brackish water area of the planned construction site and the drying rate determined in the reed rhizosphere drying rate calculating step, the reed rhizosphere groundwater salinity calculating step for determining the reticulated groundwater salinity of the reed rhizosphere,
The period during which the groundwater level is lower than the reed rhizosphere from the reed rhizosphere groundwater salinity determined in the reed rhizosphere groundwater salinity calculation step and the reed rate determined in the reed rhizosphere dry rate calculation step. A rehydration rate consideration reed rhizosphere groundwater salinity calculating step of calculating reed rhizosphere groundwater salinity in consideration of the drying rate
The ground of the artificial reed field planned to be built so that the groundwater salinity of the reed rhizosphere considering the dry rate calculated in the step of calculating the reed rate considering reed rhizosphere groundwater salt satisfies the growth limit for reed salinity Artificial reed original creation method characterized by setting high.