KR100486851B1 - Water tank having multi-bulkheads and water system - Google Patents

Abstract

The present invention is to provide a water treatment multi- bulkhead water tank that is equipped with a general water treatment water treatment plant in a multi-partition structure in order to be sanitary water treatment, easy to install equipment.

The tap water treatment multi-bulk water tank of the present invention has a ring-shaped space in an inner space containing a fluid, and is formed by partitioning such a space, a coagulation chamber chamber 180, a first settling chamber 181, and a second settling chamber ( 182, a multi-partition tank structure 100 having a filter paper chamber 183, a water purification chamber 184; An agitator 200 installed in the agglomeration paper chamber 180 to mix and agglomerate the raw water flowing from the raw water supply pipe 102; A sludge discharge bottom structure 400 formed at the bottom of the first and second settler chambers 181 and 182 and having a sludge discharge pipe 420 piped thereto; At least one filter paper (700) having at least one or more overflow pipes (600) for introducing water in the second settling chamber (182); A backwash filter paper structure 800 disposed below the filter paper 700; Filtration yarn surface washer 900 disposed on top of the filter paper (700).

Description

WATER TANK HAVING MULTI-BULKHEADS AND WATER SYSTEM}

The present invention relates to a water purification multi- bulkhead water tank, and more particularly, to a high-capacity stainless steel multi-barrier storage means having excellent structural stability, hygienic and semi-permanent use, which is provided with a water supply system for treating raw water with drinking water. The present invention relates to a water treatment multi- bulkhead water tank.

In general, drinking water means drinking water that has been treated to be suitable for the normal use of natural water and natural water, as defined in the Ministry of Environment's Drinking Water Management Act amended on August 28, 1997.

That is, drinking water prepared by applying physical and chemical treatments to be suitable for eating such spring water, such as natural water (groundwater, rock water, etc.) in the rock formation, which is not harmful even if consumed for a lifetime for various harmful substances. Spring water and water resources (water sources, dams, valleys, rivers, etc.) can be classified as drinking water for drinking water.

In particular, tap water has been thoroughly managed for the health of the public because most of the people drink it economically for a lifetime.

The general water and sewage treatment system is mostly based on the floating method, and is supplied with raw water before the water treatment in dams or water sources that secure water resources such as rainwater, river water, and valley water.

Such raw water passes through ① initiation well, ② chemical input facility, ③ mixed material, ④ flocculated land, ⑤ sedimentation basin, ⑥ filter paper, ⑦ advanced water treatment facility, ⑧ water purification basin, ⑨ water pump, and so on. Is processed.

① Impingement wells distribute the flow evenly,

② Chemical input facility is a facility that automatically inputs chemicals (coagulants) such as PAC (polyaluminum chloride), aluminum sulfate, calcined lime, activated carbon into mixed paper in order to easily remove various turbidity from raw water.

③ The mixed area is a facility that uniformly mixes raw water and input chemicals with a stirrer,

④ Agglomerated paper is a facility that condenses uniformly mixed turbidity into sedimentation masses.

⑤ The sedimentation basin is a facility to sink condensed flocs and make them clear and clean.

⑥ The filter paper is a facility for filtering fine suspended solids into sand and anthracite.

⑦ Advanced water treatment facility is a facility to remove harmful substances in water through ozone contact and bioactive carbon filter.

⑧ The purified water is a facility that temporarily stores sterilization and disinfecting chemicals after purification.

⑨ The water supply pump facility is a facility for supplying tap water from purified water to consumers.

However, the conventional water treatment system is based on the flotation method, the corresponding treatment equipment (mixture paper, flocculation paper, sedimentation paper, filter paper, water purification paper, etc.) corresponding thereto is installed on the site of a very large area, or corresponding repair, There is a disadvantage in that large plant facilities are required, such as piping, buildings, civil engineering facilities.

On the other hand, among other water treatment facilities other than floating method, MACF (Micro Air Coagulate Flotation) method, lower layer laminar flow method using biofilm, reverse contact oxidation paper method, or natural vegetation method using aquatic plants and aquatic plants, or high-speed flocculation sedimentation Hollow Fiber Micro Filter or Membrane (MBR) or MBR (Membrane BioReactor) are currently applied to wastewater and water treatment, but they have a high capacity to replace the existing flotation method. Either attempting or approaching a hierarchical or technical practical step to carry out the process.

On the other hand, many researches and efforts are being attempted on the floating method or the simple water purification treatment facility using the hollow fiber filtration membrane.

However, the simplified water treatment plant has a disadvantage of using only a single water storage space and providing only water purification ability to purify drinking water from households or household units.

That is, although there is a space efficiency and ease of use as a small-capacity water treatment facility, it is not hygienic and can be performed with a large capacity.

In particular, if a water storage facility and a water treatment facility are developed that can be used semi-permanently while having a large capacity of raw water treatment in villages, towns, towns and districts, and excellent in terms of construction economy, and taking up a lot of installation sites, It will be a profitable new technology without age.

Accordingly, the present applicant has developed a cylindrical storage tank having multiple partition walls, which can store and supply a large amount of water and have no risk of being corroded or deteriorated. .

This is a patent and utility model registration application technology filed by the applicant, which is disclosed in Republic of Korea Patent Application No. 4085, 2002, and the same date dual utility model registration application No. 2272.

As illustrated in FIG. 1, the cylindrical storage tank having a conventional multiple partition wall is configured to seal a top plate (not shown) and a bottom plate 2 to the outer wall 1 so as to contain a fluid, but the outer wall 1 The inside of the cylindrical unit (3, 4, 5, 6) having a different diameter and laminated in multiple stages are arranged in multiples having a ring shape from the shaft center, the inlet through which fluid can pass through the upper and lower parts ( A plurality of partitions 10, 11, 12 having 7, 8, 9, and a plurality of chambers 13, 14, 15, divided by the outer wall 1 and the partitions 10, 11, 12, And a cylindrical body (17) consisting of 16, in the interior of the cylindrical body (17), the fluid inflow (circularly circumferentially) when the fluid received is sequentially filled in the chambers (13, 14, 15, 16). 7, 8, 9) to control the residence time and flow direction of the fluid from inlet to outlet, and Can be appropriately adjusted in accordance with the others remaining chemicals (chlorine, fluorine) in the water in one tank, there is a unique advantage that the shooter occur.

In the conventional outer wall 1 and the partition walls 10, 11, 12, both the cylindrical cylindrical units 3, 4, 5, 6 made of stainless are laminated on the bottom plate 2 of the same material, and then welded. It is fixed to each other.

Although the conventional cylindrical storage tank having multiple bulkheads has been constructed with raw materials of stainless strips of 2t to 3t, each chamber 13, 14, 15, 16, that is, the outer chamber 13 and its Since the pressures inside the chambers exerted on the partition walls 10 between the chambers 14 are parallel to each other, there is a separate interconnection in the direction perpendicular to the side surface in each partition wall 10 to the outer wall body 1. It does not require a reinforcing rod, and it is structurally and hydrodynamically strong and has a stable liquid storage performance.

Of course, the conventional cylindrical storage tank having a multi-partition wall is manufactured by the unit stacking and welding construction method is easy to manufacture without age, there is also a feature that can make a large capacity water tank in a short time.

Nevertheless, the Applicant has discovered, among the research efforts of cylindrical storage tanks with multiple bulkheads of the prior art, that such water tanks could be applied to water treatment plants or large-scale general industrial water treatment facilities as thousands of tons or more. It became.

In particular, the conventional cylindrical storage tank having a plurality of partitions partitions a chamber or a chamber divided into a plurality of partitions within one main body, and makes different chambers by the number of partitions, or the flow length and flow time of water. It is a unique structure that can be controlled.

However, the conventional cylindrical storage tank having multiple bulkheads applies only the principle that the water rotates in the circumferential direction without applying a specific external force due to the nature of the water flow inside the cylinder, and is based on the floating method for filtration, the filtration method and the water purification principle. One filtration system is not provided in one body.

An object of the present invention is to provide a general water treatment water treatment facility and a multi-partition structure inside a single body portion that does not require a large plant equipment, sanitary water treatment is possible, water purification water treatment multiple bulkheads easy to install equipment To provide a water tank.

As described above, an object of the present invention is to provide a water treatment multi-walled water tank having a ring-shaped space in an inner space containing a fluid, the agglomeration basin chamber formed by partitioning the space, a first settling chamber chamber, and a second settling chamber chamber. A multiple bulkhead tank structure having a filter paper chamber and a water purification chamber; An agitator installed in the agglomeration basin chamber to mix and agglomerate the raw water flowing into the multiple bulkhead tank structure; A sludge discharge bottom structure formed at a bottom of the first and second settling chambers in a puddle shape and piped a sludge discharge pipe; At least one filter paper having at least one overflow pipe for introducing water in the second settling chamber; A backwash filter paper structure disposed below the filter paper; It is achieved by a tap water treatment multi-bulk water tank comprising a filter sand surface washer disposed on top of the filter paper.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

In the first embodiment, Figure 1 is a perspective view for explaining a multiple bulkhead water tank according to the prior art, Figure 2 is an exploded perspective view of a water treatment multi-wall bulkhead water treatment according to a first embodiment of the present invention, Figure 3 3 is a plan view of the tap water treatment multi-partition water tank shown in FIG. 3. 4 is a cross-sectional view of the line A-A 'shown in FIG. 3, FIG. 5 is a cross-sectional view of the line B-B' shown in FIG. 3, and FIG. 6 is a cross-sectional view of the line C-C 'shown in FIG. It is a cross section. 7 is a perspective view of the first sludge collector shown in FIG. 3, FIG. 8 is a cross-sectional view of the line D-D ′ shown in FIG. 3, and FIG. 9 is a cross-sectional view of the line E-E ′ shown in FIG. 3. 10 is a cross-sectional view taken along the line F-F ′ shown in FIG. 3. 11 is an operational state diagram of the filter paper water injector illustrated in FIG. 3, and FIG. 12 is a perspective view of the second sludge collector illustrated in FIG. 3.

As shown in Figure 2, the water purification multi- bulkhead water tank of the present invention is basically based on the flotation method, the chemical injection, mixing and flocculation, sedimentation, filtration, water purification treatment of the multiple bulkhead tank structure ( In sequence).

The multi-partition tank structure 100 is supported by at least one ring-shaped first and second circular bulkheads 111 and 112 of which at least one ring shape is erected while maintaining a predetermined gap inside the outer wall body 110 and the outer wall body 110. Welding the upper plate or the roof 120 and the lower plate 130 attached to the outer wall 110 and the lower ends of the first and second circular bulkheads 111 and 112 to become the bottom of the multi-partition tank structure 100 by welding. Combined.

As illustrated in FIG. 13, the outer wall 110 and the first and second circular partitions 111 and 112 may be formed of a rectangular partition and an outer wall.

As can be seen in the partially enlarged circle, respectively, the lower plate 130 is a wave surface shape or 'V' shape formed with mountains and valleys, and is easy to discharge and clean sludge and other foreign substances as well as water flow. Of course, the shape of the surface 133 on which the outer wall 110 is to be installed in the concrete base 132 is also formed to correspond to the surface shape of the lower plate 130.

The concrete base 132 supports the lower plate 130 based on the ground and is used as a space for installing various pipes. The concrete base 132 is piped with a cleaning pipe and a sludge discharge pipe, and are coupled to penetrate through a pipe hole formed in the bottom of each chamber or sludge discharge bottom structure. However, if the multi-bulk tank structure 100 is formed in the ground, underground, underground, and for some reason, the concrete base 132 may not be necessary.

The circular discharge path 190 has a cross section of any one of an inclined, 'U', 'V', and channel cross section, and is fixed to an outer edge of the upper end portion of the outer wall body 110, and to a bottom portion thereof. The discharge pipe 191 is piped downward to collect and discharge the sludge collected by the sludge overflowed from the filter paper or the second sludge collector.

The internal volume fraction of the multiple bulkhead tank structure 100 is capable of storing and purifying water from thousands to tens of thousands of tons or more of water per day. The first, second, third, and fourth compartments that separate and separate at least one or more chambers And partition walls 141, 142, 143, and 144.

The chemical injection facility 101, the raw water supply pipe 102, the mixing and agitation stirrer 200, and at least one first, second, and third oil inside and outside the multiple bulkhead tank structure 100 The stencils 151, 152, 153, the first sludge collector 300, the sludge discharge bottom structure, the second sludge collector 500, the at least one overflow pipe 600, and the at least one filter paper 700 ), A backwash filter paper structure disposed below the filter paper 700, and a filter sand surface washer 900.

In addition, the present invention further includes a backwash water or a backwash air supply facility (not shown) for performing a backwash process of the filter sand at an outer portion or a predetermined position of the multiple bulkhead tank structure 100.

In addition, the present invention includes a control system (not shown) necessary for the overall operation control of the present invention at the management headquarters of the water supply system.

The control system controls the operation of the filtrate surface scrubber, the backwashing equipment operation control of the backwash filter paper structure, the operation control of the first sludge collector 300 and the valve opening and closing control of the sludge discharge pipe, the operation control of the second sludge collector, raw water supply It consists of normal electric control circuits for valve opening and closing control of pipes, operation control of chemical injection facilities, rotation control of mixing and flocculation agitators, and inlet and outlet flow rate control.

As shown in FIG. 3, the multiple bulkhead tank structure 100 provided in the first embodiment of the present invention has the same or similar shape as the cylindrical storage tank having the multiple bulkheads devised by the applicant of the present invention. Use stainless steel plates for water tanks or other stainless steel tanks.

In the multi-partition tank structure 100, a first circular partition wall 111, a second circular partition wall 112, and an outer wall body 110 are arranged in a radial direction from an axial center side thereof. Particularly, in the present invention, when a further separate circular partition is arranged between the first and second circular partitions 111 and 112 or the outer wall body 110, the residence time and flow of water from the inflow to the outflow It is possible to take a longer direction, and accordingly, it can be further provided with an impingement treatment, advanced water treatment and other water treatment facilities.

Each of the first and second circular bulkheads 111 and 112 and the outer wall 110 is constructed of arc-shaped panels extending by welding in the longitudinal direction so as to have different diameters and to be laminated and welded in multiple stages.

In particular, the arc-shaped panel has 'b', 'c', 'ㅁ' formed by integrally bending the upper and lower flange portions, 'ㅇ' formed by curling after bending, and 'ㄹ' made by continuous bending. It has a cross section of any one of the children's cross sections, has an integral bending structure that does not require a separate reinforcing material or a reinforcing plate, and facilitates lamination and welding, and has a relatively strong welding force.

Here, the arcuate panels extend in the circumferential direction to have a cylindrical unit shape, and are then laminated and welded as in the prior art to form the structural members of the first and second circular partitions 111 and 112 and the outer wall body 110.

In addition, each of the first and second circular bulkheads 111 and 112 and the outer wall 110 has a concrete steel panel-integrated multiple bulkhead water tank proposed by the present applicant (Patent Application No. 10-2003-0029485 or Utility Model). (Double Application No. 20-2003-0014379) is constructed as a wall of an iron panel-concrete sandwich structure containing a stainless material.

Further, rails 171 and 172 having a general 'I' cross section or rack gear shape are formed along the circumferential direction at the upper end of the second circular partition 112 and the second passage 162 and the upper end of the outer wall 110. have.

The rails 171 and 172 restrain and guide the movement (reciprocation) trajectory of the first sludge collector 300, the second sludge collector 500, and the filtrate sand cleaner 900 in the extending direction of the rail, which will be described in detail below. , And provide a path for movement.

The first and second circular bulkheads 111 and 112, the first, second, third and fourth compartment bulkheads 141, 142, 143 and 144 and the outer wall body 110 form a cohesive paper at the axial center portion. The chamber 180 is formed.

Here, raw water is supplied (W / I) to the raw water supply pipe 102 on the side of the chemical injection facility 101, and the chemicals of the chemical injection facility 101 are injected into the raw water at this time.

The raw water into which the chemical is introduced is introduced into the agglomeration basin chamber 180, then exits the first passage 161 according to the passage of time, and flows in the direction in which the mainspring of the clock is released.

Corresponding to the flow direction of the water, the first settling chamber 181 is formed on the outer periphery of the first passage 161 to the coagulation chamber chamber 180, the second passage 162 to the first settling chamber 181 At the outer periphery of the second settling chamber 182 is formed. Thereafter, the filter paper chamber 183 and the water purification chamber 184 having the backwash filter paper structure below are formed in this order.

At this time, the flocculation chamber 180 and the first settling chamber 181 pass through the first passage 161, and the first settling chamber 181 and the second settling chamber 182 are the second passage 162. Penetrates through.

The first, second, third, and fourth partition bulkheads 141, 142, 143, and 144 are at least one plates having the same size as the height of the first and second circular partitions 111 and 112 and the width therebetween. It is absent.

The first, second, third, and fourth compartment bulkheads 141, 142, 143, and 144 are laminated and welded to the same unit as the cross-sectional shape of the cylindrical unit to be welded to each other. It forms a wall.

Here, the first partition bulkhead 141 extends in the outward direction of the diameter at the right side of the first passageway 161 formed in the first circular partition wall 111, and then on the inner side surface of the second circular partition wall 112. It is fixed.

The second partition bulkhead 142 extends in the outward direction of the diameter at the right side of the second passage 162 formed in the second circular partition wall 112 and is fixed to the inner side surface of the outer wall body 110.

As the first and second compartment bulkheads 141 and 142 are arranged on the right sides of the first and second passages 161 and 162, respectively, the water flows in the spiral clockwise direction in the multi-partition tank structure 100. do.

If the first and second compartment bulkheads 141 and 142 are arranged on the left side of the first and second passages 161 and 162, the water flow in the multi-barrier tank structure 100 is spiral counterclockwise. To flow.

In addition, the third and fourth compartment bulkheads 143 and 144 may separate the filter paper chamber 183 and the water purification chamber 184 at the edges of the second settling chamber 182. It is respectively fixed between the surface and the inner surface of the outer wall (110).

The outer wall 110 has an outer surface (outer surface) coated by ceramic tiles, stone coats, dry feet, foamed foam bricks (including general paint) which can provide both heat insulation and finishing at the same time. It is finished with better sound insulation. Of course, the outer wall 110 may be treated with a separate insulation and finish.

The chemical injection facility 101 is a conventional water treatment facility for injecting coagulant chemicals such as polyaluminum chloride, polyaluminum sulfate, polyorganic aluminum sulfate, polyaluminum hydroxide chloride, and powdered activated carbon into raw water. Is piped with the raw water supply pipe (102).

The raw water supply pipe 102 is arranged on the upper part of the multiple bulkhead tank structure 100 so as to supply raw water introduced from the landing well or other place into the agglomeration chamber chamber 180, and is fixed by other supporting members. have.

The mixing and agitation stirrer 200 generates a vortex with the stirring blade 210, so that the raw water and the coagulant are well mixed (mixed), and consequently, the raw water is coagulated (lumped).

The first hole plate 151 is mounted to block the first passage 161 except for the filter hole, and the flocculated relatively large sludge is discharged from the inside of the agglomeration chamber 180 toward the first settler chamber 181. It acts as a filter to prevent outgoing.

The second and third perforated plates 152 and 153 are further mounted to at least one predetermined position of the first settler chamber 181, and are disposed perpendicular to the circumferential direction of the first settler chamber 181, respectively. Both side surfaces are fixed to side surfaces of the first circular partition wall 111 and the second circular partition wall 112.

The first sludge collector 300 is a sludge discharge bottom structure 400 that accumulates on the bottom of the first sedimentation chamber 181 using the cover plate 310 as the dog, as will be described in detail below. Sweep and discharge to the outside.

The second sludge collector 500 collects the settling sludge that accumulates on the bottoms of the first settling chamber 181 and the second settling chamber 182 at the pressurized pressure of the pump, and the circular discharge path 190 of the multiple bulkhead tank structure 100 is collected. ) And discharge to the discharge pipe (191).

The overflow pipe 600 serves to supply the water floated in the second settling chamber 182 to the filter paper 700 of the filter paper chamber 183 and the backwashing filter paper structure under the filter paper chamber 183.

The filter paper 700 serves to separate turbidity and separate various foreign substances from the water by passing water through a filter medium, filter gravel, and filter medium (anthrasite), which are based on the rapid or slow sand method. do.

The backwash filter paper structure is a lower structure that is responsible for backwashing the filter paper 700. The backwash filter paper structure supplies water or air upward from the bottom of the stainless perforated plate to separate and suspend the suspended matter attached to the surface of the perforated plate and the multilayer media. Play a role of

Filtration yarn surface washer 900 is arranged transversely between the second circular partition 112 and the outer wall 110 to the upper portion of the filter paper 700, the upper end of the second circular partition wall 112 and the outer wall (110). After reciprocating along the formed rails 171 and 172, the suspended solids, mud, etc. on the surface of the upper filtrate yarn are separated by a high pressure of water for a predetermined time interval, and then the suspended matter which floats on the water surface is called a trough. It plays a role of pushing toward the wave-shaped overflow wall 791 of the linear water repeller 790 or the circular water repeller 190.

Hereinafter, the configuration and coupling relations of the main parts of the present invention will be described in detail with reference to FIGS. 4 to 9.

As shown in FIG. 4, the agitation and mixing stirrer 200 is arranged in the coagulation paper chamber 180.

The mixing and flocculation stirrer 200 is a three to four stirring blades 210 arranged on the circumferential surface of the rotating shaft 201 corresponding to the axis of the flocculation chamber chamber 180, and rotates the upper end of the rotating shaft 201 It has a transverse support 202 possibly coupled.

The stirring blade 210 generally has a screw shape, a rectangular frame shape through which a surface except a predetermined portion is penetrated, or a spiral shape to a spiral shape.

Both ends of the horizontal support 202 is fixed by welding to the upper end of the first circular partition wall 111, the welding portion may be further provided with a separate support bracket or reinforcing member.

The motor protection casing 230 is disposed at the central portion of the horizontal support 202, and the motor and the gearbox are coupled to the inside of the motor casing 230.

The motor rotates the rotating shaft 201 at a low speed by the rotation speed of the gearbox or the torque adjusting means, and generates a relatively large torque force.

A shaft support frame 240 is formed at the core of the agglomeration paper chamber 180, and a lower end portion of the shaft 201 facing downward is rotatably coupled to the shaft support frame 240.

Accordingly, the rotation shaft support frame 240 is responsible for the load of the rotation shaft 201, and at the same time limits the swing of the rotation shaft 201 so that it can be rotated well only in the rotation direction.

On the other hand, the bottom plate 250 of the agglomeration basin chamber 180 has a centralized cone shape, and is coupled with an external open / close valve at the cone-shaped shaft and penetrated with the sludge cleaning pipe 251 placed on the concrete base 132. Plumbing

As shown in FIG. 5, the first perforated plate 151 is installed on the first circular partition wall 111 on which the first passage 161 is formed.

Both sides of the first passage 161 are provided with mounting frames 163 and 164 for mounting after inserting the first perforated plate 151 upward.

The second hole plate including the first hole plate 161 is formed with filter holes 165 having a smaller diameter in order according to the diameter of the flocculated sludge (agglomerate).

Each filter hole 165 may be further equipped with a separate spring type filtration filter, hollow fiber membrane filter, and the like. Here, the spring-type filtration filter is arranged three to four fixed shafts to maintain a constant interval in the circumferential direction, the spring wire is wound in a spiral direction as a wrap around such a fixed shaft, and the spring wire is spaced apart The foreign matter of the size corresponding to the distance is filtered. The hollow fiber membrane filter uses a conventional prototype.

The first compartment bulkhead 141 is fixed to the right side of the first passage 161 as indicated in the cross section.

Accordingly, aggregates that are well mixed with the flocculant in the flocculation paper chamber 180 and flocculated do not pass through the filter hole 165 or the filter, but only water containing particles that can pass through the filter hole or the filter. It penetrates in a direction opposite to the partition partition wall 141 and flows toward the first settling chamber 181.

That is, the water that has passed through the first hole plate 161 flows to the left by the first compartment partition wall 141, and is as much as the average circumferential distance between the first circular partition wall 111 and the second circular partition wall 112. Relatively heavy foreign matters are gradually settled and settled while flowing along the first settling chamber 181.

6 and 7, the first sludge collector 300 collects sludge, general turbidity components, and fine particles from raw water, and removes them. In the exemplary embodiment of the present invention, the first sludge collector 300 It is a device that reciprocates for a finite time between the first compartment bulkhead and the second hole plate.

To this end, the first sludge collector 300 is a driving device 320 for generating a driving force by electric force so as to move in the circumferential direction along the first rail 171 of the second circular partition wall 112, and such a driving device It is provided with a driving wheel that is rotated by the power of. The drive wheels can be tire-shaped for use on a regular rail or can be circular gears that can be coupled to a gear rail.

Outside the drive unit 320 of the first sludge collector 300 is a cantilever 330 extending in the axial direction to the vicinity of the first circular partition wall 111, and a plurality of at least one pair extending downward of the cantilever 330. Towing means 340 made of any one of a pipe member, a traction wire, and a traction chain. The towing means 340 extends downward from the cantilever 330 to near the bottom of the first settler chamber 181.

Each of the towing means 340 is coupled to the end of the cover plate 310, the end of the first settling chamber 181 with the cover plate 310 as the drive unit 320, as the drive unit 320 moves. Swept away.

Here, the cover plate 310 is formed a coupling hole that can be connected to the traction means 340, has a considerable weight so as not to float in water, and does not damage the surface of the first settling chamber 181 It is formed of a polyurethane-based resin-based material. For example, the to-be-covered plate corresponds to a thickness of about 10 to 20 cm, an area corresponding to the width of the first settler chamber 181, and a bottom plate shape (flat, 'V' shape) of the first settler chamber 181. And a flat plate shape, an inclined shape, a wedge shape, a side shape or a hook shape, a protrusion shape, a planar shape, and an uneven shape.

As shown in FIG. 3 and FIG. 8, the sludge discharge bottom structure 400 which is dug in a puddle shape is formed on the bottom plate of the first settler chamber 181.

The sludge discharge bottom structure 400 has a puddle shape that is dug into the bottom of the first settling chamber 181 and serves to collect the sludge in one place.

The sludge discharge bottom structure 400 may include a left portion 401 of the second perforated plate 152 or a left portion 401 of the third perforated plate 153, or a first partition bulkhead 141 and a second portion. It is preferable to arrange | position to either side part 402 of the partition partition 142 (refer FIG. 3).

Each sludge discharge bottom structure 400 is covered with a stainless plate of the same material as the bottom plate of the first settling chamber 181, and forms a cone-shaped bottom plate 410, in the center of the bottom plate 410 The sludge discharge pipe 420 is piped. The sludge discharge pipe 420 extends outward from the concrete base 132 and is equipped with a valve for opening and closing the pipe.

When the first sludge collector 300 described above moves along the first rail 171, the cover plate 310 connected to the towing means 340 moves the sludge 30 to the inside of the sludge discharge bottom structure 400. As a result, the sludge 31 is collected in the sludge discharge bottom structure 400.

On the other hand, the sludge discharge operation to periodically discharge the sludge 31 collected in the sludge discharge bottom structure 400 is performed as follows.

During the sludge discharge operation, the first sludge collector 300 stops after moving the cover plate 310 which is the dog to the top of the sludge discharge bottom structure 400 (f). In this case, the to-be-covered plate 310 completely covers the upper opening portion of the sludge discharge bottom structure 400. Then, when the valve of the sludge discharge pipe 420 is opened, the sludge 31 of the sludge discharge bottom structure 400 is discharged to the outside through the sludge discharge pipe 420 by the pressure difference (S / O). At this time, the cover plate 310 is bent downward by the pressure difference to close the upper opening portion of the sludge discharge bottom structure 400, the water of the first settling chamber 181 is the sludge discharge pipe ( 420) can not escape well. Therefore, when the sludge 31 of the sludge discharge bottom structure 400 is almost discharged through the sludge discharge pipe 420, the water of the sludge discharge pipe 420 is closed, and the first sludge collector ( 300 returns to its original position (g).

9, at least one overflow pipe 600 is shown.

Each overflow pipe 600 is fixed in the form of a cantilevered hollow tube extending from the top of the third compartment bulkhead 143 toward the second settler chamber 182, wherein the third compartment bulkhead 143 and Piped through. Each of the overflow pipes 600 may be manufactured by a pipe member having a plurality of overflow holes formed therein. In addition, each of the overflow pipes 600 matches the cutting line with the axial center, and then cuts in the axial direction of the pipe to form a semicircular pipe, block the left end portion with a semicircular plate member, and the right end portion penetrate the third compartment bulkhead. It has a weir shape welded to the site.

That is, the overflow pipe 600 is a weir type such as a weir or an orifice type such as a hole.

Accordingly, when the water flows up by the level of water installed therein, the overflow pipe 600 overflows the opened upper portion of the overflow hole or the semi-circular pipe, and flows into the filter paper chamber 183.

The number and diameter of the installation of the overflow pipe 600 are determined according to the flow rate of the water and the capacity (performance) of the filter paper.

The overflow pipe 600 is also equipped with a valve that selectively opens and closes so that filtration can be continued at the other filter paper when cleaning one filter paper.

As shown in FIG. 10, the filter paper chamber 183 includes, from top to bottom, a filter sand surface washer 900 having a straight drain 790, at least one filter paper 700, and a backwash filter paper. It is composed of a structure (800).

A straight retreat 790 similar to a general trap is fixed to the fourth compartment bulkhead 144 and connected to the outer or circular discharge path of the outer wall body 110 through the discharge pipe 792.

In this case, the linear wastewater collector 790 is made of stainless steel, and has a capacity of about 20% of the maximum discharged water, so that the linear wastewater discharger 790 is completely horizontal and is completely horizontal. It is installed at the same level and its type is wear or orifice type.

The installation height of the straight drain 790 corresponds to the height of the filter paper 700 and is installed at a height lower than that of the vertical frame 801 of the filter paper 700.

On the other hand, the installation height of the filter paper 700 depends on the thickness of the backwash filter paper structure 800 and the installation height of the overflow pipe 600.

The circular discharge path and the linear discharge path 790 serve to discharge the suspended matter, mud, etc. attached to the surface of the filter sand by the water pressure sprayed from the filter sand surface washer 900 together with the discharge.

Filtration yarn surface washer 900 is a drive motor, a drive gear box, a driving wheel, etc. along a pair of straight rail 172 supported on the outer wall 110 and the second circular partition wall. It is made to reciprocate by.

The driving device 910 and the roller support are fastened to both ends of the hollow leg pipe 920 across the outer wall 110 and the second circular partition wall.

Filtration yarn surface washer 900 is a washing water injection pump for receiving the water from the outside, or to suck the water on the filter paper to distribute the high pressure to the drive unit 910, or to transfer the high pressure water from the external injection pump Receiving piping structure.

Here, the piping structure is a structure in which high pressure water is transferred to the inside of the hollow leg pipe 920, and a manufacturing method thereof depends on a conventional hydraulic line piping technique. In particular, a plurality of nozzle members 930 are piped to the lower circumferential surface of the hollow leg pipe 920 to receive high pressure water.

The nozzle members 930 extend downward from the hollow leg pipe 920 to be immersed in the water of the filter paper 700, and are arranged in a plurality while maintaining a predetermined distance in the axial direction of the hollow leg pipe 920. The nozzle member 930 consists of at least one nozzle and a connection pipe.

The high pressure water supplied from the washing water injection pump or the outside is moved to each nozzle member 930 through the hollow leg pipe 920, and then sprayed toward the surface of the filter yarn in the water of the filter paper 700.

The filter paper 700 may be arranged in the filter paper chamber 183 in pairs so that the other filter paper continues to purify while one filter paper is cleaned and backwashed.

Each filter paper 700 is based on the rapid or slow sand method, and water (W) flowing from the overflow pipe 600 through the multi-layer media 750 such as filter sand, filter gravel, and filter material (anthrasite). Is filtered.

At the bottom of the multi-layer media 750, a backwash filter paper structure 800 similar to the quick filter bottom collecting device is placed at the bottom of the filter paper chamber 183.

The backwash filter paper structure 800 is a structure for supporting the multilayer filter 750. The backwash filter paper structure 800 is also provided with only one or a pair to continuously carry out water treatment during the cleaning and backwashing of the filter sand.

The backwash filter paper structure 800 may include any one of a strainer block, a strainer-type perforated block, a general perforated block, a threaded tip tape block, and a stainless perforated plate 810 in the form of an intermediate partition of the vertical frame 801. It is used as.

In particular, the stainless perforated plate 810 in the present invention is a plate member having a plurality of holes fixed to the outer wall body 110, the second circular partition wall, the third partition partition 143 and the vertical frame 801 located around the four. .

In each hole of the stainless perforated plate 810, a spring type filtration filter 811 as described above is disposed to collect rectified water while preventing the outflow of the filtration yarn.

In addition, the stainless steel perforated plate 810 is equipped with a strainer (812: strainers) separately to drop water, air or water and the filter medium between the collision, friction, or water pressure during backwashing, so that the turbidity is collected in a straight drain on the top of the filter paper. 790 is a device to let out. Strainer 812 can use the product name HH-ST-W, HH-ST-AW of Korea 'Hanhim Technologies' for water backwash, water and air backwash.

A backwash piping member 870 for supplying backwash water to backwash air is piped into the lower space 860 of the stainless hole plate 810. The outer end of the backwash piping member 870 is piped with backwash water or backwash air supply.

In addition, the water purification pipe member 880 is piped through the lower space 860 and the space of the water purification chamber 184 of the stainless steel hole plate where the filtered water is collected, so that the multilayer media 750 and the stainless hole hole plate ( Water that has passed through the filtration filter 811 of 810 flows to the water purification chamber 184.

As shown in FIGS. 3 and 11, during backwashing and filtrate surface washing, the filtrate surface washing machine 900 reciprocates along a pair of straight rails 172, and at the backwashing piping member 870. Backwash water and backwash air flow into the lower space 860 of the stainless perforated plate 810 (A / I).

In the nozzle of the filter yarn surface washer 900, the high-pressure wash water washes the surface of the filter yarn upper portion and detaches the suspended material, the mud, and the microorganism from the filter yarn.

At the same time, the backwash water or the backwash air introduced into the lower space 860 passes through the multilayer media 750 through the strainer 812 and is suspended or adsorbed between the multilayer media 750. It separates and supports the material.

In particular, suspended matter, mud, and microorganisms suspended and desorbed in the operating direction of the filter sand surface cleaner 900 are discharged to the outside through the linear discharge vessel 790 and the discharge pipe 792 and are transferred to other sludge treatment facilities. .

The water purification chamber 184 is a space surrounded by the fourth compartment partition wall, the second compartment partition wall, the second circular partition wall 112, and the outer wall body 110, and is a space that stays for a predetermined time before water is introduced into the next water purification facility. .

In addition, the water purification chamber 184 of the present invention is divided into a high water purification treatment facility and a water purification facility by providing a separate partition bulkhead and a connecting pipe (not shown) between the fourth compartment bulkhead and the second compartment bulkhead. Can be.

The water discharge pipe member 109 piped through the water purification chamber 184 is piped to the water supply pump facility and supplies drinking water to the water supply pump facility that can be safely and safely consumed by the consumer (CW / O).

As shown in FIG. 12, the second sludge collector 500 sucks sludge deposited in the lower part of the first sedimentation chamber 181 and the second sedimentation chamber 182, general turbidity components, and fine particles and discharges them to the outside. As an embodiment of the present invention, the sludge suction operation is performed while reciprocating for a finite time interval in the circumferential direction along the rails 171 and 172 of the second circular partition wall 112 shown in FIG. Reference).

To this end, the operating range of the second sludge collector 500 is limited by the control system of the management headquarters of the water supply system in consideration of the operating range of the first sludge collector 300.

The second sludge collector 500 includes a driving motor 510 coupled with a driving motor and a driving wheel that generate a driving force by electric force so as to move circumferentially along the rail 171 on the second circular bulkhead 112. do.

The first manifold pipe 511 and the sludge discharge pipe 521 penetrated are coupled to the driving device 510.

The sludge discharge pipe 521 is supported by the roller support 520 movably coupled to the rail 172 on the outer wall body 110, the end of which is placed on the top of the circular discharge path 190.

The first joint pipe 511 connected to the external pressure generating pump is coupled to the driving device of the second sludge collector 500.

The first joint pipe 511 is a piping device capable of mechanically hinged operation (m) while transmitting pressurization pressure.

The first joint pipe 511 is a cantilevered hollow tube 512, its second joint pipe 513, and the second joint pipe 513 extending downward through the extension pipe 514, and At the bottom of the extension pipe 514 has a sludge suction pipe 515 piped in the 'T' shape.

The second joint pipe 513 is also a piping device capable of mechanically hinged operation (k) while transmitting a pressurization therein.

The cantilevered hollow pipe 512 and the extension pipe 514 and the sludge suction pipe 515 coupled to the first joint pipe 511 and the second joint pipe 513 are hinged by a manpower of a worker or by a traction facility such as a hoist. After operation (k, m), it is selectively disposed to the first settling chamber 181 and the second settling chamber 182.

Thereafter, the second sludge collector 500 moves along the rails 171 and 172 on the second circular partition wall 112 and the outer wall body 110 by the driving force of the driving device 510. The sludge of the second settling chamber 182 is sucked by pressurization.

The sludge sucked in this way is collected toward the circular discharge path 190 through the sludge discharge pipe 521 and then discharged to the sludge treatment facility.

In the second embodiment, the water treatment multi- bulkhead water tank according to the present invention has a rectangular, rectangular box-shaped layout as the rectangular multi-barrier tank structure 100 'with reference to the plan view of FIG. Except for the same as the first embodiment except for the detailed description thereof will be omitted.

In the present invention configured as described above, the water purification treatment that can be used semi-permanently with the structural rigidity and large capacity of water storage capacity and all the advantages of concrete and stainless steel as a multi-barrier structure for consumers who want a hygienic and durable water treatment facility and a water tank There is an effect that a multiple bulkhead water tank is provided.

In addition, the water purification multi- bulkhead water tank of the present invention performs a series of water treatment system systematically in a single structure, it is possible to easily install a small and medium-sized water purification equipment without the need for large-scale plant facilities and buildings. There is an advantage.

In addition, the water purification treatment multi- bulkhead water tank of the present invention has the advantage that it is possible to easily install a large-scale water purification equipment by increasing the circular partition or partition bulkhead according to the purified water and the purified water treatment time.

In addition, the tap water treatment multi-bulk water tank of the present invention is not only completely perform the tap water purification treatment inside the water tank, but also can be installed by connecting the same type of multi-bulk tank tank by modules, mass production of the desired water quality There is an advantage to this.

In addition, the water treatment multi- bulkhead water tank of the present invention is provided with a plurality of discharge pipe drainage, drainage, filter sand cleaning equipment (filter surface cleaning and backwashing equipment), various types of sludge collectors, and the like to be cleaned and maintained. It is very easy to manage.

In addition, the preferred embodiment of the present invention is disclosed for the purpose of illustration, those skilled in the art will be able to various modifications, changes, additions, etc. within the spirit and scope of the present invention, such modifications and modifications belong to the following claims You will have to look.

1 is a perspective view for explaining a multiple bulkhead water tank according to the prior art,

2 is an exploded perspective view of a water treatment multi-partition water tank according to the first embodiment of the present invention;

3 is a plan view of the tap water treatment multi-partition water tank shown in FIG.

4 is a cross-sectional view taken along the line A-A 'shown in FIG. 3;

FIG. 5 is a cross-sectional view taken along the line BB ′ shown in FIG. 3;

6 is a cross-sectional view taken along the line C-C 'shown in FIG.

7 is a perspective view of the first sludge collector shown in FIG.

8 is a cross-sectional view of the line D-D 'shown in FIG.

9 is a cross-sectional view taken along the line E-E 'shown in FIG. 3;

10 is a cross-sectional view of the line F-F 'shown in FIG.

11 is an operating state of the filter paper water injector shown in FIG.

12 is a perspective view of the second sludge collector shown in FIG.

13 is a plan view of a water treatment multi-wall bulkhead water treatment according to a second embodiment of the present invention.

           ♠ Explanation of symbols on the main parts of the drawing ♠

100: multiple bulkhead tank structure 111: first circular bulkhead

112: second circular bulkhead 180, 181, 182, 183, 184: chamber

200: stirrer 300, 500: first, second sludge collector

400: sludge discharge bottom structure 420: sludge discharge pipe

600: overflow pipe 700: filter paper

800: backwash filter paper structure 900: filter sand surface cleaner

Claims (10)

delete delete It has a ring-shaped space in the inner space for the fluid, The multi-partition tank structure 100 having the aggregated paper chamber 180, the first settler chamber 181, the second settler chamber 182, the filter paper chamber 183, and the water purification chamber 184 formed by partitioning the space. ; An agitator (200) installed in the agglomeration chamber chamber (180) to mix and agglomerate raw water introduced into the multi-partition tank structure (100); A sludge discharge bottom structure 400 formed at the bottom of the first and second settler chambers 181 and 182 and having a sludge discharge pipe 420 piped therein; At least one filter paper (700) having at least one or more overflow pipes (600) for introducing water in the second settler chamber (182); A backwash filter paper structure 800 disposed below the filter paper 700; Including a filter yarn surface washer 900 disposed on top of the filter paper 700, The multi-partition tank structure 100 includes at least one first and second partition walls 111 and 112 of a ring-shaped structure, which are stacked on top of each other while maintaining a predetermined interval inside the outer wall body 110; A roof (120) supported by the outer wall body (110); A lower plate 130 attached to the lower ends of the outer wall body 110 and the first and second partition walls 111 and 112 to become a bottom of the multiple partition tank structure 100; Water purification water treatment multi-partition water tank including first, second, third, and fourth partition bulkheads 141, 142, 143, and 144 for separating and separating the chambers 180, 181, 182, 183, and 184. To The first and second partitions 111 and 112 are further provided with at least one of the first, second and third perforated plates 151, 152 and 153 for filtering the flocculated sludge. Tap water treatment multi bulkhead water tank. It has a ring-shaped space in the inner space for the fluid, The multi-partition tank structure 100 having the aggregated paper chamber 180, the first settler chamber 181, the second settler chamber 182, the filter paper chamber 183, and the water purification chamber 184 formed by partitioning the space. ; An agitator (200) installed in the agglomeration chamber chamber (180) to mix and agglomerate raw water introduced into the multi-partition tank structure (100); A sludge discharge bottom structure 400 formed at the bottom of the first and second settler chambers 181 and 182 and having a sludge discharge pipe 420 piped therein; At least one filter paper (700) having at least one or more overflow pipes (600) for introducing water in the second settler chamber (182); A backwash filter paper structure 800 disposed below the filter paper 700; Including a filter yarn surface washer 900 disposed on top of the filter paper 700, The multi-partition tank structure 100 includes at least one first and second partition walls 111 and 112 of a ring-shaped structure, which are stacked on top of each other while maintaining a predetermined interval inside the outer wall body 110; A roof (120) supported by the outer wall body (110); A lower plate 130 attached to the lower ends of the outer wall body 110 and the first and second partition walls 111 and 112 to become a bottom of the multiple partition tank structure 100; Water purification water treatment multi-partition water tank including first, second, third, and fourth partition bulkheads 141, 142, 143, and 144 for separating and separating the chambers 180, 181, 182, 183, and 184. To Fixed to the outer edge of the upper end portion of the outer wall 110, the water discharge passage 190 having any one of the cross section of the inclined, 'U' shape, 'V' shape, channel type, and the discharge path 190 Water treatment water treatment multi-partition water tank, characterized in that it further comprises a discharge pipe 191 piped downward from the bottom portion. It has a ring-shaped space in the inner space for the fluid, The multi-partition tank structure 100 having the aggregated paper chamber 180, the first settler chamber 181, the second settler chamber 182, the filter paper chamber 183, and the water purification chamber 184 formed by partitioning the space. ; An agitator (200) installed in the agglomeration chamber chamber (180) to mix and agglomerate raw water introduced into the multi-partition tank structure (100); A sludge discharge bottom structure 400 formed at the bottom of the first and second settler chambers 181 and 182 and having a sludge discharge pipe 420 piped therein; At least one filter paper (700) having at least one or more overflow pipes (600) for introducing water in the second settler chamber (182); A backwash filter paper structure 800 disposed below the filter paper 700; Including a filter yarn surface washer 900 disposed on top of the filter paper 700, The multi-partition tank structure 100 includes at least one first and second partition walls 111 and 112 of a ring-shaped structure, which are stacked on top of each other while maintaining a predetermined interval inside the outer wall body 110; A roof (120) supported by the outer wall body (110); A lower plate 130 attached to the lower ends of the outer wall body 110 and the first and second partition walls 111 and 112 to become a bottom of the multiple partition tank structure 100; Water purification water treatment multi-partition water tank including first, second, third, and fourth partition bulkheads 141, 142, 143, and 144 for separating and separating the chambers 180, 181, 182, 183, and 184. To The first and second bulkheads 111 and 112 and the outer wall 110 are formed by bending the upper and lower flange portions integrally with the letter 'c', 'c', 'ㅁ', 'o' and ' Water purification water treatment multi-partition water tank having a cross-section of any one of the r 'character cross section, further comprising an arc-shaped panel extending by welding in the longitudinal direction. delete delete It has a ring-shaped space in the inner space for the fluid, The multi-partition tank structure 100 having the aggregated paper chamber 180, the first settler chamber 181, the second settler chamber 182, the filter paper chamber 183, and the water purification chamber 184 formed by partitioning the space. ; An agitator (200) installed in the agglomeration chamber chamber (180) to mix and agglomerate raw water introduced into the multi-partition tank structure (100); A sludge discharge bottom structure 400 formed at the bottom of the first and second settler chambers 181 and 182 and having a sludge discharge pipe 420 piped therein; At least one filter paper (700) having at least one or more overflow pipes (600) for introducing water in the second settler chamber (182); A backwash filter paper structure 800 disposed below the filter paper 700; In the tap water treatment multi-partition water tank including a filter sand surface washer 900 disposed on the filter paper 700, At least one first and second sludge which discharges sludge of the first settler chamber 181 and the second settler chamber 182 while moving along the rails 171 and 172 of the multi-partition tank structure 100. Water treatment water treatment multi-partition water tank, characterized in that it further comprises a collector (300, 500). It has a ring-shaped space in the inner space for the fluid, The multi-partition tank structure 100 having the aggregated paper chamber 180, the first settler chamber 181, the second settler chamber 182, the filter paper chamber 183, and the water purification chamber 184 formed by partitioning the space. ; An agitator (200) installed in the agglomeration chamber chamber (180) to mix and agglomerate raw water introduced into the multi-partition tank structure (100); A sludge discharge bottom structure 400 formed at the bottom of the first and second settler chambers 181 and 182 and having a sludge discharge pipe 420 piped therein; At least one filter paper (700) having at least one or more overflow pipes (600) for introducing water in the second settler chamber (182); A backwash filter paper structure 800 disposed below the filter paper 700; Including a filter yarn surface washer 900 disposed on top of the filter paper 700, The multi-partition tank structure 100 includes at least one first and second partition walls 111 and 112 of a ring-shaped structure, which are stacked on top of each other while maintaining a predetermined interval inside the outer wall body 110; A roof (120) supported by the outer wall body (110); A lower plate 130 attached to the lower ends of the outer wall body 110 and the first and second partition walls 111 and 112 to become a bottom of the multiple partition tank structure 100; Water purification water treatment multi-partition water tank including first, second, third, and fourth partition bulkheads 141, 142, 143, and 144 for separating and separating the chambers 180, 181, 182, 183, and 184. To The backwashing filter paper structure 800 supports the multilayer media 750 in the form of an intermediate partition wall, and the outer wall body 110, the second partition wall 112, the third partition partition wall 143, and a vertical frame 801. And a stainless perforated plate (810) fixed to the) and equipped with at least one spring type filtration filter (811) for preventing the outflow of the filtration yarn. delete