KR200279030Y1 - Apparatus for Screening of Algae - Google Patents

Abstract

The present invention relates to a screen device for removing algae. The screen device according to the present invention is used for a water purification plant including a settling tank and a filter paper. The screen apparatus includes a mesh screen for screening particles containing algae during the course of the settling water, And a support plate for supporting the mesh frame at both ends thereof.

By using the screen device according to the present invention, it is possible not only to remove most of the algae and flocs including the attached algae at the stage where the settling water flows through the overflowing section of the settling tank during the flow from the settling tank to the filter paper, Even non-biological particles can be removed. Accordingly, it is possible to improve the quality of purified water by preventing the particles flowing from the settling paper from causing clogging of the filter paper, as well as to remarkably reduce the backwashing cost of the filter paper. Further, the screen device according to the present invention has an advantage that it can be easily applied without modification of existing facilities.

Description

[0001] Apparatus for Screening of Algae [

The present invention relates to a screen device for improving the quality of filter paper influent water by removing algae from sedimentation basin. More particularly, the present invention relates to a screen device that is installed in a weir of a sedimentation unit to filter algae and floc particles present in the overflow flowing into the filter paper from the sedimentation basin to improve the quality of the influent of the filter paper.

Water use is soaring due to the current economic growth and rapid improvement of living standards due to urbanization. On the other hand, the emission of various kinds of sewage including urban sewage, industrial wastewater and livestock wastewater due to urbanization is increasing day by day. For this reason, the water shortage problem is emerging as a serious social problem in most of the middle and advanced countries including Korea. Therefore, in each country, in order to solve the eutrophication, occurrence of phytoplankton, and this hobby in the lake and river which are not only the value of natural ecosystem but also the health of the people, .

When we look at the process of producing tap water, we first pour water from the water supply at the water source and sink the sand in the water. After that, various kinds of water treatment chemicals are put in the chemical input room, and water and chemicals are mixed well in the mixed paper. After that, the flocculants and sediments are entangled in the agglomerate, and then sedimentation of the entangled sediment is made. Then, after filtering more thoroughly in the filter paper, chlorine is put in the chlorine input chamber to kill the remaining bacteria. After that, the fully processed water is stored and the water is supplied to each household. There is a problem that the filter paper is clogged due to particles such as algae which are not precipitated in the sedimentation tank and flowed into the filter paper as it is. Since the occluded filter paper must be periodically cleaned, there is a problem in that the cost is large.

The amount of phytoplankton biomass increases due to the increase of nitrogen (N) and phosphorus (P) nutrients due to water pollution, which causes reduction of transparency and water treatment efficiency, and also causes problems such as clogging of the filter paper do. This phenomenon of clogging of the filter paper is particularly concentrated on the period from the winter to the spring, and most of it is due to diatoms. Stephanodiscus algae and Synedra algae are the main causes of clogging of filter paper during the period from winter to spring. Aulacoseira and Synedra series Of the bird is the cause of the clogging of the filter paper. These algae were not properly treated, but they acted as a major cause of filter paper clogging to the filter paper. For the normal functioning of the filter paper, the occluded filter paper must be regularly cleaned, and such backwashing is costly.

It is an object of the present invention to provide a screen device capable of preventing the clogging of the filter paper and significantly reducing the backwashing cost of the filter paper. It is also an object of the present invention to provide a screen device which can be easily applied without modification of existing facilities.

1 is a perspective view showing a screen device for removing algae according to the present invention.

2 is a perspective view showing a settling basin provided with a screen device for removing algae according to the present invention.

FIG. 3 is a plan view showing a flow in which the sedimentation water flows from the sedimentation tank to the filter paper.

Description of the Related Art [0002]

1: Screen device 2: Support plate

3: Mesh Frame 4: Mesh

In order to achieve the above object, the screen device for removing algae according to the present invention is a device for use in a water purification plant including a settling tank and a filter paper, A mesh frame for supporting the mesh, and a support plate for supporting the mesh frame at both ends thereof.

In the aforementioned screen device for algaecure, the mesh is characterized in that the size of the hole is larger than 100 μm and smaller than 200 μm.

In the screen device for algaecure, the size of the mesh hole is larger than 100 mu m and smaller than 150 mu m.

In the screen device for algaecure, the mesh-attached mesh frame is attached to the support plate at an angle of 55 to 65 degrees from the bottom. The most preferred angle is 60 degrees.

The screen device further includes a brush to continuously remove flocs attached to the mesh during the screening process to prevent clogging.

The screen device may further include a water supply means to continuously remove flocs attached to the mesh during the screening process to prevent clogging.

Hereinafter, the screen device according to the present invention will be described in more detail.

In the process of the treatment water flowing from the sedimentation reservoir to the filter paper, the water is freely passed and the filter is filtered in consideration of the particle size of the algae and the algae causing the filter paper occlusion at the stage where the supernatant liquid of the sedimentation tank flows over the filter paper will be. The crude product is in a state in which the biological activity is substantially inferior due to the influence of chlorine treatment, contact with coagulating chemical, and the like in the step of flocculation-flocculation process, which is the previous stage of the water treatment process. Therefore, the filtration by screening according to the present invention can be easily applied. FIG. 3 is a plan view showing a flow in which the sedimentation water flows from the sedimentation tank to the filter paper. When flocculent precipitates and clear water rises in the clarifier, the water flows over the overflow and flows toward the filter paper. However, in order to solve the problem that the particles including the algae are not precipitated and flow over the overflow portion and toward the filter paper, it is necessary to provide the screen device 1 of Fig. 1 on the both side portions as shown in Fig. to be. It is most preferable that the screen apparatus 1 is installed at an angle of 30 degrees from the ridge portion. That is, when the screen device is inclined to the final weir of the sedimentation paper, the adhered particles flow down together with the accumulated flow velocity of the adhered particles and the accumulating weight of the adhered particles, whereby the adhered particles are slid downward, Finally, the principle of natural settling down to the sedimentation basin is applied. 1 is a perspective view of a screen device 1 according to the present invention. The screen device 1 includes a mesh 4 for filtering a mesh, a mesh frame 3 for supporting the mesh 4, and a support plate 2 for supporting the mesh frame 3 on both sides thereof have.

Hereinafter, the present invention will be described in more detail with reference to an embodiment of the screen device according to the present invention, but this is only for the purpose of illustrating the present invention, and the scope of the present invention is not limited thereto.

Example

<Comparative Example>

In order to prepare for the effect of the screen device according to the present invention, the inventors of the present invention first investigated and analyzed the data necessary for understanding the actual condition of the conventional water purification plant as follows.

1. Survey on the distribution of algae in water purification plants in Korea

The present inventors analyzed the algae contained in the raw water and sediment water in November 2001 in 29 major water treatment plants in Korea to investigate the types and distribution of the algae present in the raw water of the water purification plant and in the sedimentation waters. As a result, 88 species of 48 freshwater algae were observed. Among them, 27 species of diatoms (30.7%), 36 species of cyanobacteria, 13 species of cyanobacteria (14.8%), green algae of 17 genera, 39 species (44.3% The algal blooms accounted for about 90% of diatoms, cyanobacteria and green algae, with one species of one species (1.1%), three species of euglena (3.4%) and three species of three species (3.4%). That is, the distribution of algae in the raw water of the water purification plant and the overflowing waters of the settling basin was in the order of green algae> diatom algae> cyanobacteria> euglena algae / gypsy algae>

The major constituents of the taxa observed in the water treatment plant were diatoms Achnanthes , Asterionella , Aulacoseira , Cyclotella , One species of Cymbella , one species of Diatoma , one species of Fragilaria , one species of Gomphonema , one species of Gyrosigma , one species of Melosira , Two species of Navicula , one species of Nitzschia , one species of Pinnularia , one species of Stephanodiscus , two species of Synedra and one species of Tabellaria , Are classified into three species of Anabaena , two species of Aphanizomenon , one species of Botryococcus , one species of Merismopedium , two species of Microcystis , (Oscillatoria) 3 species, and formate Medium (Phormidium) 1 species, the green alga is bad Tina Sturm (Ac tinastrum ), three Ankistrodesmus , one Chlamydomonas , two Closterium , two Coelastrum , and a Cosmarium ), Two species of Crucigenia , one species of Dictyosphaerium , one species of Golenkinia , one species of Gonium , two species of Koliella , Tiny Titanium (Micractinium) 1 species, pediah Sturm (Pediastrum) 5 species, ssene des mousse (Scenedesmus) 13 species, Selena Sturm (Selenastrum) 1 species, star Wu last room (Staurastrum) 1 species and hardware Stella (Westella) One species of Ceratium , one species of Peridinium , one species of Dinobryon species of yellow monocotyledonous species, two species of Euglena species of euglena species, two species of Tracheolo One species of Trachelomonas , one of the genus Pseudomonas species is Chroomonas , Rhodomonas and Cryptomonas ), Respectively.

In addition, diatoms and cyanobacteria were found to be the main species in the sediment collected from the scum and concrete wall matrix of sedimentation area. The attached algae of the water purification plant, especially, have high density of cyanobacterium, and diatoms have different characteristics depending on the season. However, because of the typical floatability and adhesion, they can consider two characteristics of chemical agglomeration and spontaneous effect.

The attached algae were composed of 13 genera of 25 species of diatoms, and 5 species of 4 species of cyanobacteria and total of 17 genera and 30 species. The taxa are diatoms classified into two classes : Achnanthes , Asterionella , Aulacoseira , Cyclotella , Cymbella , One species of Diatoma , one species of Diploneis , one species of Fragilaria , one species of Gyrosigma , one species of Navicula , three species of Nitzschia Two species of Synedra and one species of Tabellaria were cyanobacteria, one of Lyngbya , one of Nostoc , two of Oscillatoria , Phormidium ). In the sedimentation area of the water purification plant, the cyanobacteria which are deep inside the scum, the outside or the wall substrate are overgrown by the majority of the species not observed in the raw water and can be regarded as the taxa native to the water purification plant. It is thought that it will make a great contribution to the clogging of the filter paper together with the floating birds.

2. Water quality investigation of water treatment stage of water treatment plant

PH, electrical conductivity, turbidity, TDS, fluorescence measurement, chlorophyll a concentration and aquatic inorganic nutrients were analyzed by water treatment stage. That is, raw water, mixed index, flocculation index, sediment index, filtered water and purified water were investigated. The results are shown in Table 1 below for the water quality of the resin water purification plant, and the water quality for the Cheongju water purification plant is shown in Table 2 below.

As shown in the above tables, turbidity decreased 79.4% in the resin water purification plant and 86.3% in the Cheongju water purification plant from the raw water to the clarifier. On the other hand, the fluorescence value decreased by 70.9% in the resin plant and 81.7% in the Cheongju plant. However, in the case of the resin water treatment plant, the turbidity tends to increase temporarily (2.57 → 4.31) immediately after contact with chlorine, which is presumably due to the destruction of the crude after concentration of the algae and contact with chlorine. It is also found that the turbidity of the precipitate index is significantly reduced in the filtered water. This means that the suspended solids present in the settling index are substantially filtered through the filter paper. Therefore, it can be assumed that the filter paper will be occluded by the adhesion of the floats.

3. Measurement of cell number of algae by water treatment stage of water purification plant

(1) Preparation of sample

In order to measure the change of algae distribution (cell number) according to the water treatment stage of the water treatment plant, the inventors of the present invention measured samples at the resin water purification plant and the Cheongju water purification plant in June and November from the seawater, the mixed paper, the coagulating paper, the sedimentation paper, . Freshwater algae were tested for quantitative analysis and attached birds for qualitative analysis. The samples for quantitative analysis were fixed in Lugol solution immediately after sampling at the apex of each plant in the water purification plant, and were transported to the laboratory in the ice box. Adhesive algae were collected from sedimentation basin and collected mainly on floating scum and wall surface within 1m depth of sedimentation basin. In particular, cyanobacteria and adherent algae were first observed as unfixed samples, and the fixed samples were sufficiently settled in the laboratory for more than one week. Then, the supernatant was removed and concentrated to 10 to 20 times and reconstituted with 1% formalin. At this time, in order to prevent the photo-oxidation of the sample, it was wrapped with aluminum foil.

(2) Measurement of cell count of algae

In order to identify the diatoms, nitric acid (HNO ₃ ) of the same amount (1: 1) was mixed with 10 ml of the concentrated sample and boiled. A small amount of potassium dichromate (K ₂ Cr ₂ O ₇ ) Respectively. After the acid treatment, the treated reagent was washed with distilled water several times using a centrifuge, and then a permanent sample was prepared with Pleurax encapsulant, which was identified by observation under an optical microscope. In order to identify the species, it was identified by observation at a high magnification of × 400 or × 1000. A portion of the concentrated sample was uniformly dispersed in a Sedgwick-Rafter chamber having a volume of 1 ml, and the number of cells was counted while observing under an optical microscope (× 200). The results are shown in the table below. Table 3 below shows the data for the resin purification plant, and Table 4 below shows the data for the Cheongju purification plant.

Door \ Sample Station R1 R2 M C S F T Basilario Picaea ( Bacillariophyceae ) Asterionella formosa Aulacoseira ambigua Aulacoseira ambigua f. Asteraceae spp . spiral Aulacoseira granulata Aulacoseira granulata var. aulacoseira granulata var. Standing Bartica (Aulacoseira subartica) as angustissima aura kose a cycle L'Hotel La Atocha Moose (Cyclotella atomus) cycle Iberotel La menegini Ana (Cyclotella meneghiniana) cycle Iberotel La Stelliga Gera (Cyclotella stelligera) infrastructure Zilla Leah Black tonen system (Fragilaria crotonensis) Guy Gyrosigma spencerii Melosira varians Stephanodiscus hantzschii f. tenuis sinedra acus ( Synedra acus ) 232 · 3 · 22222 · rr 24 占 쏙옙 3r22r 占 r2 r2 · 33 · 32r · r · rr 22233 · 32r · r2r2 2 r r 2 ······························ ······························ CyanopicAea ( Cyanophyceae ) Gloeothece sp. Oscillatoria sp. ... · 3 ·2 2r ·2 ... ... Chloropicame ( Chlorophyceae ) Ella nose Sturm Retina particulate retum (Coelastrum reticulatum) ellagic nose Sturm Sperry kyum (Coelastrum sphaericum) Peddie Sturm Bo rayiah num (Pediastrum boryanum) Peddie Sturm duplex (Pediastrum duplex) var. Scenedesmus bicaudatus Scenedesmus longispina Scenedesmus quadricauda var. gracillium Scenedesmus bicaudatus Scenedesmus longispina Scenedesmus quadricauda var. parvus ... · 3 ··· 2r · 3 · 322 · 322. ... ... ...

1: <10, 2: <100, 3: 1: <1: 2, <1: <1,000, 4: <10,000, 5:> 10,000 cells / ml)

Door \ sampling station R M C S F T Basilario Picaea ( Bacillariophyceae ) Asterionella formosa Aulacoseira ambigua Aulacoseira ambigua f. Asteraceae spp. spiral Aulacoseira granulata Aulacoseira granulata var. aulacoseira granulata var. as angustissima aura kose Italic car (Aulacoseira italica) cycle Rotel la menegini Ana (Cyclotella meneghiniana) PRA Gillet Ria croissant tonen sheath (Fragilaria crotonensis) this to suspend Sigma Serena (Gyrosigma spencerii) Sine drive ahkuseu (Synedra acus) 1323332rr1 13r3432rr2 2323432222 22.2 ... 1 ······················ ······················ Cyanophyceae Gloeothece sp. Oscillatoria proteus Oscillatoria sp. 2r ... r ... ... ... ... Chloropicame ( Chlorophyceae ) Scenedesmus ellipsoideus , · r · · · ·

1: <10, 2: <100, 3: <1,000, 4: <10,000 (where R1 is the settling state, M is the mixed paper, C is the agglomerating paper, S is the sedimentation paper, F is the filter paper, , 5: &gt; 10,000 cells / ml).

As shown in the above table, it can be seen that there is a large amount of algae in the sedimentation index (S), while no algae is present in the filtration index (F). Therefore, it was easy to see that the algae were caught while passing through the filter paper, and the filtered algae would remain in the filter paper, resulting in the clogging of the filter paper.

The resin water purification plant was dominated by the diatom Auracoseira and the cyanobacteria Oscillatoria . The number of algae cells in each stage of the resin water purification plant was determined to be 560 cells / ml in chlorine contact, 2,618 cells / ml in raw water, 1,369 cells / ml in raw water, 779 cells / ml in coagulation index, The index was 101 cells / ml. From this data, the algae content of the precipitation index was 18.0% and the water treatment efficiency was 82.0%. On the other hand, in the case of Cheongju water purification plant, Aulacoseira , which is a diatomaceous species, is dominant. The sedimentation index for the raw water was 6.2%, and the sedimentation index was 115 cells / ml. The sedimentation index of the raw water was 1,855 cells / ml, the mixing index was 2,570 cells / ml, the cohesion index was 2,787 cells / Therefore, the water treatment efficiency was 93.8%. As a result, the influence of algae on the filter paper can be seen in the range of 6.2 to 18.0%. Therefore, it can be seen that the rate of algae removal (82.0%, 93.8%) is proportional to the turbidity reduction rate (70.9%, 81.7%). In other words, turbidity reflects the interrelationship with the effects of algae.

Example

<Examples 1 to 5: Evaluation of Turbidity and Elimination Efficiency of Screen Device According to the Present Design>

After the screen device 1 having the support plate 2, the mesh frame 3 and the mesh 4 according to the present invention was mounted on the overflow portion of the sedimentation basin, the screen device 1 was installed in June and November 2001 The effluent removal efficiency of sedimentation watersheds was evaluated for the Cheongju and Cheongju water purification plants. As mentioned above, since the turbidity and the algae are related to each other, the turbidity of the settling water before and after the screen device was measured and compared. In addition, the efficiency of removing the algae by the screen device was calculated by measuring the number of algae cells before the settling water passed through the screen device and the number of algae cells after passing through the screen device. The material of the mesh 4 was silk (Switzerland) widely used for the plankton net production. The size of the screen device 1 was 100 cm x 18 cm and the sizes of the mesh holes were 80 mu m (Example 1), 100 mu m (Example 2), 125 mu m (Example 3) and 150 mu m (Example 4) And 200 mu m (Example 5). As shown in FIG. 1, in each of the screen devices 1 covered with the respective meshes, the mesh frame 3 was fixed to the support plate 2 so that both ends of the mesh frame 3 were obliquely fixed at an angle of 60 degrees from the bottom . This screen device 1 was installed in the sedimentation wall sweep portion as it is. That is, the mesh frame 3 of the screen device 1 installed at the ridge portion is set at an angle of 60 degrees from the water surface and at an angle of 30 degrees from the settler flow portion. The turbidity and the number of algae cells were measured after 20 to 30 minutes of observation. The particulate matter attached to the screen device 1 was then scraped with a soft brush and used for various analyzes.

(1) Turbidity removal efficiency

The turbidity removal efficiency of the resin water purification plant is shown in the following Table 5, and the turbidity removal efficiency of the Cheongju water purification plant is shown in Table 6 below.

Size of mesh hole of screen device (탆) Turbidity (NTU) Before passing mesh After passing mesh Turbidity Removal Rate (%) 80 0.44 0.34 22.0 0.34 0.33 0.46 0.29 100 0.35 0.30 37.0 0.40 0.28 0.63 0.28 125 0.32 0.28 76.6 0.58 0.30 2.81 0.28 150 0.70 0.30 40.4 0.40 0.25 0.32 0.30 200 0.55 0.27 37.2 0.35 0.27 0.40 0.27

Size of mesh hole of screen device (탆) Turbidity (NTU) Before passing mesh After passing mesh Turbidity Removal Rate (%) 80 1.41 0.57 44.0 0.85 0.55 0.75 0.56 100 0.88 0.56 49.6 0.76 0.57 1.82 0.62 125 1.33 0.61 45.9 0.82 0.58 1.19 0.61 150 2.13 0.65 65.2 0.95 0.58 2.35 0.65 200 0.92 0.63 70.2 4.30 0.64 1.31 0.67

As shown in the above table, the turbidity tendency was irregular according to the size of the hole of the mesh 4 of the screen device 1, but the turbidity removal effect was 22.0 to 76.6% in the case of the resin water purification plant and 44.0 to 70.2 %.

(2) Algae removal efficiency

Table 7 shows the results for the resin water treatment plant, and Table 8 shows the results for the Cheongju water treatment plant.

Door \ sampling station 80 100 125 150 200 B A B A B A B A B A Basilario Picaea ( Bacillariophyceae ) Asterionella linearis ( Asterionella formosa ) Aulacoseira granulata var. angustissima Cyclotella meneghiniana Navicula sp. Navicula sp. Stephanodiscus hantzschii f. tenuis 3 ... ··2···· ... · 2 · 2 · · · ... 2······ ······One ····2·· ·····One· SinoPichea ( Cyanophyceae ) Chroococcus mimutus Microcystis aeruginosa Oscillatoria sp. ... ... ·2· ... ··2 ... ... ... 2r 112 Chloropicame ( Chlorophyceae ) Coelastrum reticulatum Scenedesmus acutus var. Scenedesmus longispina Scenedesmus quadricauda var. acutus Scenedesmus longispina Scenedesmus quadricauda var. parvus ·2·· ... ... ... 22 ... 2··· ... ... ...

R: rare, 1: <10, 2: <100, 3: <1,000, 4: &lt; 10,000, 5: &gt; 10,000 cells / ml)

Door \ sampling station 80 100 125 150 200 B A B A B A B A B A Basilario Picaea ( Bacillariophyceae ) Asterionella ambigus Asterionella granulata Aulacoseira granulata var. Asterionella granulata var. angustissima Aulacoseira italica Cyclotella meneghiniana Fragilaria crotonensis Gyrosigma spencerii Navicula sp. australia Cyclotella meneghiniana Fragilaria crotonensis Gyrosigma spencerii Navicula sp. Synedra acus 332? 3? 2? ... · 3321 · · · 1 ... 2r3 · 1 ... r r332 ···· 1 ... 333 ... 2 2 11 CyanopicAea ( Cyanophyceae ) Oscillatoria sp. · · · · · · 3 · · ·

R: rare, 1: <10, 2: <100, 3: <1,000, 4: &lt; 10,000, 5: &gt; 10,000 cells / ml)

As shown in the above table, the removal efficiency of algae was 72.4 to 100%. In the case of Example 1 (80 占 퐉) and Example 2 (100 占 퐉), the algae removal effect was excellent, but the passage force passing through the screen device 1 tended to decrease with time. In addition, although the above-described disadvantages can be solved, the algae removal efficiency of Example 4 (150 占 퐉) and Example 5 (200 占 퐉) was somewhat lowered to 72.4 to 98.6%. In the case of Example 3 (125 mu m), the tidal removal efficiency was high and the tendency to decrease the permeability through the screen device 1 was not seen either. Therefore, it can be seen that the largest algal removal efficiency is obtained when the mesh hole size is 125 mu m (Example 3). This size is effective to remove the diatom synedra. Taken together, the size of the mesh hole should be at least 100 μm to prevent the decrease of the hydraulic force penetrating the screen device, and it should be less than 150 μm to keep the algae removal efficiency high.

&Lt; Examples 6 and 7: Full-scale application test >

In the full-scale test (secondary field test), the size of the screen device 1 is 250 cm x 18 cm x 2 and the size of the mesh 4 holes is 125 mu m (Examples 6) and 200 mu m (Example 7) Screen apparatus 1 was used. The full-scale test (secondary field test) has been focused on solving the headloss that may occur at the shear of the overflowing section due to clogging of the screening device by supplementing the primary test, and proposes an alternative . As a result, the turbidity was 96.9% in Example 6 (125 탆) and 94.9% in Example 7 (200 탆), while the case of Example 6 (125 탆) was slightly more effective, but the difference was not large. The results for the removal of algae are shown in the table below.

Door \ sampling station S 125 200 Basilario Picaea ( Bacillariophyceae ) Asterionella ambigua Asterionella ambigua ( Asterionella ambigua) morphotyp. spiralis Aulacoseira granulata Aulacoseira granulata var. angustissima Auracoseira granulata var. angustissima morphotyp. curvata asterisks Lionel called a tally car (Asterionella italica) asterisks Lionel called standing Bartica (Asterionella subartica) cycle Iberotel La menegini Ana (Cyclotella meneghiniana) cycle Iberotel La Capital Telly Gera (Cyclotella pseudostelligera) cycle Iberotel La Stelliga Gera (Cyclotella stelligera ) Cymbella sp . Gyrosigma spencerii Melosira varians Navicula sp. Pinnularia sp. Synedra acus 3233222213 ·· r · 11 1, 1 r, ·········One······ CyanopicAea ( Cyanophyceae ) Anabaena affinis Microcystis aeruginosa Microcystis ichthyoblabe Phormidium sp. Anabena affinis Microcystis aeruginosa Microcystis ichthyoblabe Phormidium sp. 43 · 5 22 ... 23 Chloropicame ( Chlorophyceae ) Closterium sp. Staurastrum sp. ·One ... ... Yuglenopikea ( Euglenophyceae ) Euglena sp. · · · Cryptophycia ( Cryptophyceae ) Chromomonas sp. Cryptomonas sp. ... ... ...

R: rare, 1: <10, 2: <100, 3: <1,000, 4: <10,000, 5: : &Gt; 10,000 cells / ml)

As shown in the above table, the algae removal rate of Example 6 (125 mu m) was 99.6%, and the algae removal rate of Example 7 (200 mu m) was 99.1%. Therefore, in combination with the experiments of the first to fifth embodiments, it can be concluded that the size of the hole of the mesh (4) in the screen device according to the present invention is determined to be 100 μm to 200 μm. It has been confirmed that algae filtered through the screen device 1 according to the present invention are also filtered to algae and aggregates (flocs) by algae other than the originally intended diatoms, Synedra acus , such as scum , As well as algae as well as abiotic particles. The raw material passing through the screen device 1 without being filtered is extremely fine in size, and the diatoms Auracoseira subartica , the Cyclotella pseudostelligera , the Cyclotella stelligera , ( Cyclotella stelligera ), the cyanobacteria Anabaena affinis , and Microcystis aeruginosa . However, the influence of the clogging of the filter paper due to the amount of the algae passing through the screen device is very small, because it is within 2% as compared with the initial amount flowing into the filter paper overflowing from the overflow portion of the settler without applying the screen device according to the present invention. It is judged to be small.

However, the inventors of the present invention have found that the effect of the present invention can be further improved if particles such as algae adhere to the screen device 1 and clogging of the screen occurs to prevent head loss that may occur at the front end of the overflow portion of the sedimentation basin Respectively. This is described in Examples 8 to 9 below.

&Lt; Example 8 >

The screen device 1 was further provided with a brush in the same manner as in the sixth and seventh embodiments. There may arise a problem that the mesh of the screen device 1 is clogged due to the stickiness of the floc during the overflow of the sedimentation water through the overflow portion, leading to the head loss of the sedimentation basin. In order to prevent this, the brush serves to scrape off the particles adhering to the mesh 4 while the sedimentation water flows out of the sedimentation tank. Therefore, the effect of the present invention can be further improved by preventing the occlusion of the mesh.

&Lt; Example 9 >

And the means for spraying water at the rear end of the screen device 1 were further provided, as in the sixth and seventh embodiments. The problem of clogging of the mesh can be solved by preventing the particles from adhering to the mesh 4 by spraying water at the rear end of the screen device 1. [ Therefore, the effect of the present invention can be further improved.

By using the screen device according to the present invention, it is possible not only to remove most of the algae and flocs including the attached algae at the stage where the settling water flows through the overflowing section of the settling tank during the flow from the settling tank to the filter paper, Even non-biological particles can be removed. Therefore, the backwashing cost of the filter paper can be remarkably reduced by preventing the particles flowing from the settling paper from causing clogging of the filter paper. Further, the screen device according to the present invention has an advantage that it can be easily applied without modification of existing facilities.

Claims (6)

An apparatus for use in a water purification plant including a sedimentation tank and a filter paper, And a support plate for supporting the mesh frame at both ends of the mesh frame, the mesh frame supporting the mesh, and the support plate supporting the mesh frame at both ends. The screen device for removing algae in a water treatment plant according to claim 1, wherein the mesh has a hole size of more than 100 탆 and not more than 200 탆. The screen device for removing algae of a water purification plant according to claim 2, wherein the size of the mesh holes is larger than 100 μm and smaller than 150 μm. The screen device of claim 1, wherein the mesh-attached mesh frame is attached to the support plate at an angle of 55 to 65 degrees from the bottom. The screen device for algae removal according to claim 4, wherein the screen device further comprises a brush to continuously remove the flocs attached to the mesh during the screening process to prevent clogging. The screen device for algae removal according to claim 4, wherein the screen device further comprises a water supply means for continuously removing flocs attached to the mesh during the screening process to prevent clogging.