CN212102289U - High-efficient industry pure water production system - Google Patents

Abstract

The utility model discloses a high-efficiency industrial pure water production system, which comprises a buffer water tank, a quartz sand filter, an activated carbon filter, a medicament adding device, a precision filter, a reverse osmosis device and a sterilization device which are connected in sequence through a water conveying pipeline; the inlet tube setting of buffer tank is at its middle part, buffer tank's outlet pipe sets up at its top, be provided with the filter screen on buffer tank's the outlet pipe. The utility model discloses a high-efficient industry pure water production system, former feed water advance to go into the buffer tank nature deposit with prefilter, and the overflow reentries quartz sand filter, activated carbon filter and filters, and it removes a large amount of impurities, then gets into the medicament and adds the device, and with the antisludging agent mixing of interpolation, carries out depth filtration through precision filter, reverse osmosis unit again, can obtain industry pure water after sterilizing through sterilizing equipment at last.

Description

High-efficient industry pure water production system

Technical Field

The utility model relates to a pure water preparation field, in particular to high-efficient industry pure water production system.

Background

At present, the demand of industrial water is more and more great, and the preparation scheme of the commonly used industrial pure water is as follows: the raw water is sequentially treated by a quartz sand filter, an activated carbon filter, a precision filter, a reverse osmosis device, a sterilization device and the like to prepare pure water with the quality meeting the requirements.

The quartz sand filter is used for primarily filtering raw material water, and can effectively intercept and remove suspended matters, organic matters, colloidal particles, microorganisms, chlorine, odor, partial heavy metal ions and the like in the water. The quality of the treatment effect of the quartz sand filter has great influence on the subsequent operation. When the quartz sand filter is used, particularly under the action of long-term scouring of water, fine-grain (or micro-fine-grain) quartz sand originally existing in the filter layer or fine-grain quartz sand generated due to the scouring action inevitably passes through the bottom of the filter layer along with water flow to enter filtered water, and enters the next section of operation if the quartz sand is not treated. After the accumulated amount is large, the subsequent operation and equipment are affected greatly, for example, an activated carbon filter possibly adopted in the subsequent operation section is blocked, a precision filter and a reverse osmosis device are blocked or damaged, and extra abrasion is caused to pump equipment. Therefore, quartz sand entering the filtered water is prevented or reduced as much as possible, and the method plays an important role in the whole pure water preparation system. Patent 201810607590.2 discloses a quartz sand filter for water treatment, which discharges water through an overflow pipe, and reduces the amount of quartz sand entering into the filtered water by using the settling action of the overflow pipe. However, the method still has the defects that the quartz sand is prevented from being discharged to the next operation along with the rising of the water flow only by the gravity sedimentation of the vertical pipe section of the overflow pipe, the effect is not obvious, for example, when the water flow speed is high, a large amount of quartz sand can still pass through the top of the vertical pipe section of the overflow pipe to enter the next operation under the action of the water flow; or the fine quartz sand can pass the top of the vertical pipe section of the overflow pipe to enter the next operation under the action of small water flow. If the settling effect of the quartz sand is to be provided, the height of the vertical pipe section of the overflow pipe can only be increased, but too high is obviously not suitable and does not show. So its effect of blocking the quartz sand from entering the next operation is to be enhanced.

In addition, in order to improve the water quality, a scale inhibitor is usually added during the preparation of pure water, and the scale inhibitor can effectively prevent the water quality from generating dirt and improve the water quality. The effect of dispersing and uniformly mixing the scale inhibitor and water has great influence on the improvement of the drug effect and the water quality, and in order to improve the uniform mixing effect of the scale inhibitor and the water, a medicament stirring and mixing device is particularly arranged in some products. For example, patent CN201821483241.6, it discloses an industry pure water treatment facility, wherein, handles incasement portion and is provided with the (mixing) shaft, and (mixing) shaft fixed surface is connected with the stirring piece, and (mixing) shaft one end fixedly connected with motor, processing case top pipe connection have the scale inhibitor case, and it drives the stirring piece through the motor and rotates, carries out abundant stirring to scale inhibitor and water in the processing case, can promote pure water treatment quality and effect. But it requires the additional introduction of a drive device: motors, which increase power consumption and cost.

Therefore, there is a need for a more reliable industrial pure water production scheme that overcomes the above-mentioned deficiencies.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that to the not enough among the above-mentioned prior art, provide a high-efficient industry pure water production system.

In order to solve the technical problem, the utility model discloses a technical scheme is: a high-efficiency industrial pure water production system comprises a buffer water tank, a quartz sand filter, an activated carbon filter, a medicament adding device, a precision filter, a reverse osmosis device and a sterilization device which are sequentially connected through a water conveying pipeline;

the water inlet pipe of the buffer water tank is arranged in the middle of the buffer water tank, the water outlet pipe of the buffer water tank is arranged at the top of the buffer water tank, and the water outlet pipe of the buffer water tank is provided with a filter screen;

the quartz sand filter comprises a first tank body, a first water distributor, a protection filter plate, a quartz sand filter layer, a bottom filter plate and a water collecting pipe, wherein the first water distributor, the protection filter plate, the quartz sand filter layer, the bottom filter plate and the water collecting pipe are sequentially arranged in the first tank body from top to bottom;

first water-locator is including the column box body and the cone form box body that from top to bottom set gradually, a plurality of water distribution holes have been seted up to the bottom of cone form box body, form a plurality of water distribution chambeies through a plurality of division boards in the first water-locator, the water distribution chamber include with the perpendicular chamber section of the entry end intercommunication of column box body and with the slope chamber section of perpendicular chamber section bottom intercommunication, the bottom of slope chamber section with water distribution hole intercommunication.

Preferably, the water conveying pipeline comprises a first water conveying pipe connected with a water inlet pipe of the buffer water tank, a second water conveying pipe connected between a water outlet pipe of the buffer water tank and the quartz sand filter, a third water conveying pipe connected between the quartz sand filter and the activated carbon filter, a fourth water conveying pipe connected between the activated carbon filter and the medicament adding device, a fifth water conveying pipe connected between the medicament adding device and the reverse osmosis device, and a sixth water conveying pipe connected between the reverse osmosis device and the sterilization device;

the first water delivery pipe, the third water delivery pipe, the fourth water delivery pipe and the fifth water delivery pipe are respectively provided with a first water pump, a second water pump, a third water pump and a fourth water pump, and the precision filter is arranged on the fifth water delivery pipe.

Preferably, the quartz sand filter layer comprises quartz sand filled between the protection filter plate and the bottom filter plate and a plurality of corrugated filter plates arranged between the protection filter plate and the bottom filter plate at intervals;

the wave-shaped filter plate comprises a first wave-shaped filter plate, a second wave-shaped filter plate and a third wave-shaped filter plate which are arranged from top to bottom in sequence;

the diameters of filter holes formed in the first wave-shaped filter plate, the second wave-shaped filter plate and the third wave-shaped filter plate are reduced in sequence, and the two ends of the three wave-shaped filter plates are fixedly connected with the inner wall of the first tank body.

Preferably, the quartz sand between the protection filter plate and the first corrugated filter plate forms a first filter layer, the quartz sand between the first corrugated filter plate and the second corrugated filter plate forms a second filter layer, the quartz sand between the second corrugated filter plate and the third corrugated filter plate forms a third filter layer, and the particle sizes of the quartz sand in the first filter layer, the second filter layer and the third filter layer are sequentially reduced.

Preferably, the quartz sand filter further comprises an overflow water outlet pipeline connected with the water outlet end of the water collecting pipe;

the overflow water outlet pipeline comprises a first pipe section communicated with the water outlet end of the water collecting pipe, a vertical ascending pipe section communicated with the tail end of the first pipe section, a V-shaped sand settling pipe section communicated with the tail end of the ascending pipe section, an S-shaped climbing pipe section communicated with the sand settling pipe section and a second pipe section communicated with the S-shaped climbing pipe section.

Preferably, the first pipe section is arranged obliquely, the first end of the first pipe section, which is connected with the water collecting pipe, is lower than the second end of the first pipe section, which is connected with the vertical ascending pipe section, and the bottom of the first end of the first pipe section is provided with a first sand discharge port;

the V-shaped first top end of the sand setting pipe section is communicated with the tail end of the vertical ascending pipe section through an arc pipe section, and the V-shaped second top end of the sand setting pipe section is communicated with the bottom end of the S-shaped climbing pipe section; and a second sand discharge port is formed in the V-shaped bottom end of the sand settling pipe section.

Preferably, the inner wall of the arc-shaped pipe section is provided with a first arc-shaped sand-resisting sheet;

the S-shaped climbing pipe section is obliquely arranged, and a plurality of second arc-shaped sand-blocking sheets are arranged on the inner wall of the S-shaped climbing pipe section at intervals;

the second arc-shaped sand preventing sheets are arranged in a downward inclined mode, namely the upper ends of the second arc-shaped sand preventing sheets are connected with the inner wall of the S-shaped climbing pipe section, and the lower ends of the second arc-shaped sand preventing sheets are far away from the inner wall of the S-shaped climbing pipe section.

Preferably, the medicament adding device comprises a blending box, a turbine box arranged on the upper part of the blending box, a stirring impeller arranged in the blending box, a driving turbine arranged in the turbine box and coaxial with the stirring impeller, and a medicament storage tank arranged on the blending box.

Preferably, the scale inhibitor is stored in the medicament storage tank, and the medicament storage tank is connected with the blending box through a medicament pipeline;

the water inlet end of the turbine box is connected with the third water conveying pipe, and the water outlet end of the turbine box is connected to the blending box through a seventh water conveying pipe;

the water entering from the water inlet end of the turbine box flows into the mixing box through the water outlet end of the turbine box after passing through the driving turbine so as to drive the driving turbine to rotate, and the stirring impeller is driven to rotate by the driving turbine.

Preferably, a medicine feeding device is arranged in the blending box, and comprises a medicine feeding pipe section communicated with the medicament pipeline, a conical mixing pipe section connected to the lower end of the medicine feeding pipe section, a water outlet ball connected to the lower end of the conical mixing pipe section, and a water inlet pipe section of which the first end is connected with the outer wall of the conical mixing pipe section and the second end is connected with the seventh water conveying pipe;

a plurality of water outlet through holes are formed in the outer wall of the water outlet ball body; the water outlet through hole is a conical hole, and the diameter of the water outlet through hole is gradually reduced from the inner wall of the water outlet ball body to the outside.

The first end of the water inlet pipe section is tangent to the outer wall of the conical mixing pipe section.

The utility model has the advantages that: the utility model discloses a high-efficient industry pure water production system, raw materials water enters the buffer tank nature deposit earlier with the prefilter, and the overflow reentries quartz sand filter, active carbon filter filtration, and it removes a large amount of impurity, then gets into medicament interpolation device, and with the scale inhibitor mixing that adds, carries out deep filtration through precision filter, reverse osmosis unit, can obtain industry pure water after sterilizing through sterilizing equipment at last;

the utility model can lead the inlet water into the quartz sand filter uniformly through the first water distributor, so that the inlet water is distributed on the whole surface of the top of the filter layer uniformly, thereby the whole filter layer can be fully utilized for filtering;

the utility model discloses a set up overflow outlet pipe way, utilize first pipeline section, first arc to hinder the sand piece and can once block fine grain quartz sand, the structure sand setting pipeline section through the V style of calligraphy can block fine grain quartz sand once more along with the motion of rivers, climb the pipeline section through the S type, the sand piece is hindered to the second arc and can carry out the cubic to fine grain quartz sand and block, thereby can greatly reduce the amount that fine grain quartz sand that leaks down in the filter layer gets into next technology section along with the drainage, thereby show the negative effects of the fine grain quartz sand that reduces to follow-up operation that spills;

the utility model filters water by three wave-shaped filter plates to form three filter layers with wave-shaped bottom surfaces, which can increase the retention time of water in the filter layers and enhance the contact effect between water and filter media, thereby improving the filtering effect; three corrugated filter plates are used for supporting, so that the phenomenon that media in each filter layer are mutually permeated can be prevented, and three relatively independent and stable filter layers can be formed in the first tank body;

the utility model has the advantages that the stirring impeller can stir the water and the scale inhibitor in the mixing box body, thereby greatly improving the mixing effect of the scale inhibitor and the water; by arranging the turbine box, the rotation of the stirring impeller can be realized by utilizing water inflow, a driving mechanism can be omitted, the equipment is simplified, and the energy consumption is reduced; through setting up into medicine device, make water and antisludging agent mix for the first time at toper mixing tube section, then it is internal to get into the mixing box again, carries out the secondary mixing under impeller's stirring effect to can guarantee the mixing effect of antisludging agent and water, improve the effect that prevents quality of water and produce the dirt, can promote ultimate quality of water.

Drawings

FIG. 1 is a schematic structural view of a high-efficiency industrial pure water production system according to the present invention;

fig. 2 is a schematic structural view of a quartz sand filter according to embodiment 1 of the present invention;

fig. 3 is a schematic structural view of a first water distributor in embodiment 1 of the present invention;

fig. 4 is a schematic structural diagram of an overflow water outlet pipeline of a quartz sand filter according to embodiment 2 of the present invention;

fig. 5 is a schematic structural view of a sand setting pipe section and an S-shaped climbing pipe section according to embodiment 2 of the present invention;

fig. 6 is a schematic structural view of an activated carbon filter according to example 2 of the present invention;

fig. 7 is a schematic structural view of a chemical adding apparatus according to embodiment 3 of the present invention;

fig. 8 is a schematic structural view of a medicine feeding device according to embodiment 3 of the present invention;

fig. 9 is a schematic structural view of a water outlet hole in embodiment 3 of the present invention.

Description of reference numerals:

1-buffer water tank; 10-water inlet pipe of buffer water tank; 11-water outlet pipe of buffer water tank;

2-quartz sand filter; 20-a first tank; 21-a first water distributor; 22-protection filter plate; 23-quartz sand filter layer; 24-bottom filter plate; 25-a water collecting pipe; 26-overflow water outlet pipeline; 27-a water collecting cavity;

210-a cylindrical cartridge; 211-pyramid-shaped box body; 212-a partition plate; 213-water distribution cavity; 214-a vertical cavity section; 215 — inclined cavity section;

230-quartz sand; 231 — first wave filter plate; 232-second wave filter plate; 233-third filter plate; 234 — first filter layer; 235 — a second filter layer; 236-a third filter layer;

260 — a first tube segment; 261-a vertical riser section; 262-sand setting pipe section; 263-S-shaped climbing pipe section; 264-a second pipe section; 265-first sand discharge port; 266-a second sand discharge port; 267-an arc-shaped pipe section; 268 — first arc-shaped sand-blocking sheet; 269-second arc-shaped sand-blocking sheet;

3-an activated carbon filter; 30-a second tank; 31-a second water distributor; 32-an activated carbon filter layer; 33-a water collecting pipe;

4-a medicament adding device; 40-mixing box body; 41-turbine box; 42-stirring impeller; 43 — drive the turbine; 44-medicament storage tank; 45-medicament line; 46-a drug feeding device;

400-a rotating shaft; 401-a bearing; 402-sealing ring;

460-a drug intake section; 461-conical mixing tube section; 462-water outlet ball; 463-water inlet pipe section; 464-the first end of the water inlet pipe section; 465-the second end of the water inlet pipe section; 466-water outlet through hole;

5, a precision filter;

6, a reverse osmosis device;

7-a sterilization device;

8-water conveying pipeline; 80-a first water delivery pipe; 81-a second water conveying pipe; 82-a third water delivery pipe; 83-a fourth water delivery pipe; 84-a fifth water conveying pipe; 85-a sixth water conveying pipe; 86-a seventh water conveying pipe;

90-a first water pump; 91 — a second water pump; 92-a third water pump; 93-fourth water pump.

Detailed Description

The present invention is further described in detail below with reference to examples so that those skilled in the art can implement the invention with reference to the description.

It will be understood that terms such as "having," "including," and "comprising," as used herein, do not preclude the presence or addition of one or more other elements or groups thereof.

As shown in fig. 1, the high-efficiency industrial pure water production system of the present embodiment includes a buffer water tank 1, a quartz sand filter 2, an activated carbon filter 3, a chemical adding device 4, a precision filter 5, a reverse osmosis device 6, and a sterilization device 7, which are sequentially connected through a water pipeline 8.

The utility model is used for preparing industry pure water, the former feed water is advanced to go into 1 natural deposition of buffer tank, and the overflow reentries quartz sand filter 2, activated carbon filter 3 filters, and it detach a large amount of impurity, then gets into the medicament and adds device 4, with the antisludging agent mixing of interpolation, carries out depth filtration through precision filter 5, reverse osmosis unit 6 again to improve the pure water quality, carry out the pure water discharge as after the disinfection of disinfecting through sterilizing equipment 7 at last, for the use. The precise filter 5 (also called a cartridge filter) can prevent the fine particles in the combined filter 1 from flowing into the subsequent reverse osmosis membrane, the pore diameter of the filter medium is preferably 1 μm to 5 μm, and the specific type of the precise filter 5 can be selected from conventional products. The sterilization device 7 is used for sterilizing and disinfecting the water treated by the reverse osmosis device 6, and may be an ozone sterilization device, an ultraviolet sterilization device, or the like. The foregoing is a general idea of the present invention, and more specific embodiments are provided below to further explain the present invention.

Example 1

Referring to fig. 1 to 3, on the basis of the above, in the present embodiment, the water conveying pipeline 8 includes a first water conveying pipe 80 connected to the water inlet pipe 10 of the buffer water tank, a second water conveying pipe 81 connected between the water outlet pipe 11 of the buffer water tank and the quartz sand filter 2, a third water conveying pipe 82 connected between the quartz sand filter 2 and the activated carbon filter 3, a fourth water conveying pipe 83 connected between the activated carbon filter 3 and the chemical adding device 4, a fifth water conveying pipe 84 connected between the chemical adding device 4 and the reverse osmosis device 6, and a sixth water conveying pipe 85 connected between the reverse osmosis device 6 and the sterilization device 7;

the first water pipe 80, the third water pipe 82, the fourth water pipe 83 and the fifth water pipe 84 are respectively provided with a first water pump 90, a second water pump 91, a third water pump 92 and a fourth water pump 93, and the precision filter 5 is arranged on the fifth water pipe 84. The fourth water pump 93 is preferably a booster water pump.

The water inlet pipe 10 of the buffer water tank is arranged at the middle part of the buffer water tank, the water outlet pipe 11 of the buffer water tank is arranged at the top part of the buffer water tank, and the water outlet pipe 11 of the buffer water tank is provided with a filter screen. Raw material water enters the buffer water tank 1 through the first water conveying pipe 80 under the action of the first water pump 90 to remove partial particulate matters through natural sedimentation, primary filtration is realized, and then the raw material water enters the quartz sand filter 2 through the water outlet pipe through overflow drainage. The large particle impurities can be prevented from entering the quartz sand filter 2 by the filter screen.

Further, the quartz sand filter 2 comprises a first tank 20, a first water distributor 21, a protective filter plate 22, a quartz sand filter layer 23, a bottom filter plate 24 and a water collecting pipe 25 which are arranged in the first tank 20 from top to bottom in sequence;

the first water distributor 21 comprises a columnar box body 210 and a conical box body 211 which are sequentially arranged from top to bottom, a plurality of water distribution holes are formed in the bottom of the conical box body 211, a plurality of water distribution cavities 213 are formed in the first water distributor 21 through a plurality of partition plates 212, each water distribution cavity 213 comprises a vertical cavity section 214 communicated with the inlet end of the columnar box body 210 and an inclined cavity section 215 communicated with the bottom of the vertical cavity section 214, and the bottoms of the inclined cavity sections 215 are communicated with the water distribution holes. In the preferred embodiment, the ends of the plurality of angled cavity segments 215 are of equal cross-sectional area so that the water exiting the ends of each angled cavity segment 215 remains relatively uniform. The water distribution chambers 213 are isolated from each other to guide water. The inlet water can be uniformly guided into the quartz sand filter 2 through the first water distributor 21, so that the inlet water is uniformly distributed on the whole surface of the top of the filter layer, and the whole filter layer can be fully utilized for filtering. The protective filter plate 22 is provided with filter holes for reducing the washing of the water to the top surface of the filter layer and preventing the formation of pits due to the washing of the water.

Further, the quartz sand filter layer 23 includes quartz sand 230 filled between the protective filter plate 22 and the bottom filter plate 24, and a plurality of corrugated filter plates arranged at intervals between the protective filter plate 22 and the bottom filter plate 24; the wave filter plate comprises a first wave filter plate 231, a second wave filter plate 232 and a third wave filter plate 233 which are arranged from top to bottom in sequence; the diameters of the filter holes formed in the first, second and third corrugated filter plates 231, 232, 233 decrease in sequence, and both ends of the three corrugated filter plates are fixedly connected to the inner wall of the first tank 20. The silica sand between the protective filter plate 22 and the first corrugated filter plate 231 forms a first filter layer 234, the silica sand between the first corrugated filter plate 231 and the second corrugated filter plate 232 forms a second filter layer 235, the silica sand between the second corrugated filter plate 232 and the third corrugated filter plate 233 forms a third filter layer 236, and the particle diameters of the silica sand in the first filter layer 234, the second filter layer 235, and the third filter layer 236 are sequentially reduced.

Three filter layers with waved bottom surfaces are formed by the three waved filter plates to filter water, and due to the turbulent flow guiding effect of the waved filter plates, part of water tends to flow along a waved inclined plane, so that the retention time of the water in the filter layers can be increased, the contact effect between the water and a filter medium is enhanced, and the filtering effect is improved. The pore diameters of the upper and lower filter layers are reduced in sequence to form gradient filtration, so that the filtration efficiency and the filtration effect can be improved. The three wave-shaped filter plates are used for supporting, so that the phenomenon that media in the filter layers are mutually permeated can be prevented, and three relatively independent and stable filter layers can be formed in the first tank body 20.

Further, a water collection cavity 27 is arranged below the third corrugated filter plate 233, and the water collection pipe 25 is flatly laid in the water collection cavity 27. The water collecting pipe 25 preferably adopts a 'feng' shaped water collecting pipe 25 to improve the water collecting efficiency, and water collecting holes are densely arranged on the water collecting pipe 25.

Example 2

4-6, on the basis of the above, in the present embodiment, further, the quartz sand filter 2 further includes an overflow outlet pipe 26 connected to the outlet end of the water collecting pipe 25; the overflow water outlet pipeline 26 comprises a first pipe section 260 communicated with the water outlet end of the water collecting pipe 25, a vertical ascending pipe section 261 communicated with the tail end of the first pipe section 260, a V-shaped sand settling pipe section 262 communicated with the tail end of the ascending pipe section, an S-shaped climbing pipe section 263 communicated with the sand settling pipe section 262 and a second pipe section 264 communicated with the S-shaped climbing pipe section 263.

Further, the first pipe section 260 is arranged obliquely, the first end connected with the water collecting pipe 25 is lower than the second end connected with the vertical rising pipe section 261, and the bottom of the first end of the first pipe section 260 is provided with a first sand outlet 265; the V-shaped first top end of the sand setting pipe section 262 is communicated with the tail end of the vertical ascending pipe section 261 through an arc pipe section 267, and the V-shaped second top end of the sand setting pipe section 262 is communicated with the bottom end of the S-shaped ascending pipe section 263; the V-shaped bottom end of the sand setting pipe section 262 is provided with a second sand discharge opening 266.

Further, a first arc-shaped sand-blocking sheet 268 is disposed on the inner wall of the arc-shaped tube segment 267. More preferably, the bottom end of the first curved sand-blocking tab 268 is located at the side of the connection between the curved tube segment 267 and the vertical riser segment 261 near the vertical riser segment 261, i.e., at the right side of the inner wall of the left side of the vertical riser segment 261 in fig. 5. When fine sand rises to the arc tube section 267 along with the water flow, part of the fine sand can fall into the vertical rising tube section 261 after being blocked by the first arc sand-blocking sheets 268.

Further, the S-shaped climbing pipe section 263 is obliquely arranged, and a plurality of second arc-shaped sand-blocking sheets 269 are arranged on the inner wall of the S-shaped climbing pipe section 263 at intervals. The second arc-shaped sand-blocking sheet 269 is arranged in a downward inclined manner, i.e., the upper end of the second arc-shaped sand-blocking sheet is connected with the inner wall of the S-shaped climbing pipe section 263, and the lower end of the second arc-shaped sand-blocking sheet is far away from the inner wall of the S-shaped climbing pipe section 263.

More preferably, the first arc-shaped sand-blocking sheet 268 and the second arc-shaped sand-blocking sheet 269 are both provided with micropores, and the size of the micropores is at least smaller than the size of the filter pores of the bottom filter plate 24. The micro-pores can reduce the blocking effect on water flow and ensure the blocking of fine quartz sand.

In this embodiment, the overflow water outlet pipes 26 include two sets that are symmetrically arranged, the water inlet ends of the first pipe sections 260 of the two sets of overflow water outlet pipes 26 are both connected to the water outlet end of the water collecting pipe 25, and the water outlet ends of the two sets of overflow water outlet pipes 26 are both connected to the water inlet end of the third water pipe 82.

Under the action of long-term water flushing, a part of original fine-grain (or micro-fine-grain) quartz sand in the filter layer or fine-grain quartz sand (the part with the grain diameter smaller than the size of the filter holes on the bottom filter plate 24) generated by the flushing action inevitably passes through the bottom filter plate 24 along with water flow and enters the water collecting pipe 25, and if the part is not processed, the next section of operation is carried out. If the amount is large, the subsequent operation and equipment are adversely affected, for example, the activated carbon filter 3 in the subsequent operation section is clogged, the ultrafilter 5 and the reverse osmosis device 6 are clogged or damaged, and the pump equipment is additionally worn. The utility model discloses in, through the water of overflow outlet pipe way 26 discharge after the filtering layer is handled, the amount that fine grain quartz sand that leaks down in the filter layer gets into next technology section along with the drainage can be reduced greatly to show the negative effects of the fine grain quartz sand that reduces to spill to follow-up operation.

Specifically, the water filtered by the filter layer and a part of fine quartz sand mixed therein are discharged from the water collecting pipe 25 into the first pipe section 260 of the overflow water outlet pipeline 26, wherein the fine quartz sand moves along with the water flow, and the movement of the fine quartz sand is mainly analyzed. The first pipe section 260 is inclined upwards along the water flow direction, and a certain obstruction is provided for the movement of the fine quartz sand, when the fine quartz sand moves upwards through the vertical ascending pipe section 261, part of the fine quartz sand falls to the first pipe section 260 due to gravity, and the other part of the fine quartz sand collides with the first arc-shaped sand-blocking sheet 268 and is blocked to fall, so that the fine quartz sand falling to the first pipe section 260 slides to the first sand outlet 265 along the inclined direction to be gathered;

the fine quartz sand passing through the arc tube 267 is deposited to the second sand discharge port 266 at the bottom end of the V-shape in a large amount in the sand setting tube 262 due to the V-shape structure, and the sand setting tube 262 blocks the movement of the fine quartz sand along with the water flow again;

the fine quartz sand crossing the sand-setting pipe section 262 passes through the S-shaped climbing pipe section 263 in an inclined upward direction along an S shape, due to the design of the S-shaped structure, the water flow speed is reduced, the ascending power of the fine quartz sand is greatly reduced, and a large amount of fine quartz sand can reversely fall along the S-shaped climbing pipe section and slide into the second sand outlet 266 for gathering; in addition, the second arc-shaped sand-blocking sheet 269 in the S-shaped climbing pipe segment 263 blocks the ascending fine quartz sand again, so that the fine quartz sand cannot pass through the S-shaped climbing pipe segment 263 to reach the second pipe segment 264, and the fine quartz sand blocked by the second arc-shaped sand-blocking sheet 269 also slides to the second sand outlet 266 to be gathered. After a period of use, when the equipment is shut down, the valves at the first sand outlet 265 and the second sand outlet 266 are opened, and the fine quartz sand accumulated can be discharged. Therefore, the sand blocking effect of the overflow water outlet pipeline 26 can greatly reduce the amount of fine quartz sand (or micro-fine quartz sand) entering the next working section.

In a further preferred embodiment, the activated carbon filter 3 comprises a second tank 30, and a second water distributor 31, an activated carbon filter layer 32 and a water collecting pipe 33 which are arranged in the second tank 30 from top to bottom in sequence. The second water distributor 31 has the same structure as the first water distributor 21, and the water collecting pipe 33 used in the activated carbon filter 3 has the same structure as the water collecting pipe 25 used in the quartz sand filter 2.

Example 3

Referring to fig. 7 to 9, in a further improvement of embodiment 1 or embodiment 2, in this embodiment, the chemical adding apparatus 4 includes a kneading tank, a turbine tank 41 provided at an upper portion of the kneading tank, a stirring impeller 42 provided inside the kneading tank, a drive turbine 43 provided inside the turbine tank 41 and coaxial with the stirring impeller 42, and a chemical storage tank 44 provided on the kneading tank.

The scale inhibitor is stored in the medicament storage tank 44, and the medicament storage tank 44 is connected with the blending box through a medicament pipeline 45; the water inlet end of the turbine box 41 is connected with the third water conveying pipe 82, and the water outlet end of the turbine box 41 is connected to the blending box through the seventh water conveying pipe 86.

The water entering from the water inlet end of the turbine box 41 flows into the mixing box from the water outlet end of the turbine box 41 after passing through the driving turbine 43, so as to drive the driving turbine 43 to rotate, and the stirring impeller 42 is driven to rotate by the driving turbine 43.

The driving turbine 43 and the stirring impeller 42 are both fixed on a rotating shaft 400, the rotating shaft 400 is rotatably disposed in the mixing box 40, and the upper end of the rotating shaft extends into the turbine box 41. The upper and lower inner walls of the mixing box 40 are provided with bearings 401 to mount the rotating shaft 400, and the junction between the turbine box 41 and the mixing box 40 is further provided with a seal ring 402 (which does not affect the normal rotation of the rotating shaft 400) to prevent the water in the turbine box 41 from directly flowing down into the mixing box 40 from the junction. It is understood that the driving turbine 43, the stirring impeller 42, the rotating shaft 400, the bearing 401, etc. are preferably made of corrosion-resistant materials to prolong the service life thereof.

Under the action of the third water pump 92, water enters the turbine box 41 at a certain flow rate and contacts with the blades of the driving turbine 43, so that the driving turbine 43 is driven to rotate, and the water passing through the driving turbine 43 enters the mixing box 40 through the seventh water conveying pipe 86 and is mixed with the scale inhibitor added into the mixing box 40. Because the stirring impeller 42 and the driving turbine 43 are coaxial, the driving turbine 43 drives the stirring impeller 42 to rotate while rotating, thereby stirring the water and the scale inhibitor in the mixing box body 40, greatly improving the uniform mixing effect of the scale inhibitor and the water, and improving the effects of preventing the water quality from generating dirt and improving the pure water treatment quality. And when the water inflow is larger, the rotating speed of the driving turbine 43 is faster, and the stirring effect of the stirring impeller 42 is stronger, so that the uniform mixing degree of the scale inhibitor and water can be improved along with the increase of the water inflow and the self-adaption. The scale inhibition effect can be improved through the stirring effect, the rotation of the stirring impeller 42 can be realized through water inlet, a driving mechanism can be omitted, the equipment is simplified, and the energy consumption is reduced.

Furthermore, a medicine inlet device 46 is arranged in the blending tank, the medicine inlet device 46 includes a medicine inlet pipe section 460 communicated with the medicine pipeline 45, a conical mixing pipe section 461 connected to the lower end of the medicine inlet pipe section 460, a water outlet ball 462 connected to the lower end of the conical mixing pipe section 461, and a water inlet pipe section 463 having a first end 464 connected with the outer wall of the conical mixing pipe section 461 and a second end 465 connected with the seventh water pipe 86; a plurality of water outlet through holes 466 are formed in the outer wall of the water outlet ball 462; the outlet 466 is a tapered hole whose diameter is gradually reduced from the inner wall of the outlet ball 462. The first end 464 of the inlet leg is tangential to the outer wall of the conical mixing leg 461. A switch may be provided on the medication line 45 to control dispensing. The scale inhibitor is prepared by selecting a conventional product.

The scale inhibitor in the medicament storage tank 44 flows downwards from the medicament pipeline 45 to the medicament inlet pipe section 460 and then enters the conical mixing pipe section 461; the water (with a certain flow velocity) discharged from the water outlet end of the turbine box 41 enters the water inlet pipe section 463 through the seventh water pipe 86, then enters the conical mixing pipe section 461 along a tangent line, meets the scale inhibitor flowing vertically downwards, forms a mixing rotational flow, continues to flow downwards to the water outlet ball 462, flows in a rotational flow form on the water outlet ball 462, and then radially flows outwards from the water outlet through holes 466 densely arranged on the water outlet ball 462 to enter the mixing box body 40. Water and the scale inhibitor enter from two vertical directions in the conical mixing pipe section 461, so that the collision contact effect can be improved, and the uniform mixing effect can be further improved after the rotational flow is formed. The water outlet through holes 466 are tapered holes, so that the flow velocity of water is increased when the water flows out of the water outlet through holes, and the uniform mixing is enhanced. Wherein, water and antisludging agent carry out the first mixing in toper mixing tube section 461, then go on mixing again in the water spheroid 462 and then enter mixing box 40, carry out the secondary mixing under the stirring of impeller 4222, can guarantee the mixing effect of antisludging agent and water, improve the effect that prevents quality of water from producing the dirt, can promote quality of water.

While the embodiments of the invention have been disclosed above, it is not limited to the applications listed in the description and the embodiments, which are fully applicable in all kinds of fields where the invention is suitable, and further modifications may readily be made by those skilled in the art, and the invention is therefore not limited to the specific details without departing from the general concept defined by the claims and the scope of equivalents.

Claims (10)

1. A high-efficiency industrial pure water production system is characterized by comprising a buffer water tank, a quartz sand filter, an activated carbon filter, a medicament adding device, a precision filter, a reverse osmosis device and a sterilization device which are sequentially connected through a water conveying pipeline;

the water inlet pipe of the buffer water tank is arranged in the middle of the buffer water tank, the water outlet pipe of the buffer water tank is arranged at the top of the buffer water tank, and the water outlet pipe of the buffer water tank is provided with a filter screen;

the quartz sand filter comprises a first tank body, a first water distributor, a protection filter plate, a quartz sand filter layer, a bottom filter plate and a water collecting pipe, wherein the first water distributor, the protection filter plate, the quartz sand filter layer, the bottom filter plate and the water collecting pipe are sequentially arranged in the first tank body from top to bottom;

first water-locator is including the column box body and the cone form box body that from top to bottom set gradually, a plurality of water distribution holes have been seted up to the bottom of cone form box body, form a plurality of water distribution chambeies through a plurality of division boards in the first water-locator, the water distribution chamber include with the perpendicular chamber section of the entry end intercommunication of column box body and with the slope chamber section of perpendicular chamber section bottom intercommunication, the bottom of slope chamber section with water distribution hole intercommunication.

2. The high-efficiency industrial pure water production system according to claim 1, wherein the water delivery pipeline comprises a first water delivery pipe connected with a water inlet pipe of the buffer water tank, a second water delivery pipe connected between a water outlet pipe of the buffer water tank and a quartz sand filter, a third water delivery pipe connected between the quartz sand filter and an activated carbon filter, a fourth water delivery pipe connected between the activated carbon filter and a medicament adding device, a fifth water delivery pipe connected between the medicament adding device and a reverse osmosis device, and a sixth water delivery pipe connected between the reverse osmosis device and a sterilization device;

the first water delivery pipe, the third water delivery pipe, the fourth water delivery pipe and the fifth water delivery pipe are respectively provided with a first water pump, a second water pump, a third water pump and a fourth water pump, and the precision filter is arranged on the fifth water delivery pipe.

3. The high-efficiency industrial pure water production system according to claim 1, wherein the quartz sand filter layer comprises quartz sand filled between the protective filter plate and the bottom filter plate and a plurality of corrugated filter plates arranged at intervals between the protective filter plate and the bottom filter plate;

the wave-shaped filter plate comprises a first wave-shaped filter plate, a second wave-shaped filter plate and a third wave-shaped filter plate which are arranged from top to bottom in sequence;

the diameters of filter holes formed in the first wave-shaped filter plate, the second wave-shaped filter plate and the third wave-shaped filter plate are reduced in sequence, and the two ends of the three wave-shaped filter plates are fixedly connected with the inner wall of the first tank body.

4. The high-efficiency industrial pure water production system according to claim 3, wherein the quartz sand between the protective filter plate and the first corrugated filter plate forms a first filter layer, the quartz sand between the first corrugated filter plate and the second corrugated filter plate forms a second filter layer, the quartz sand between the second corrugated filter plate and the third corrugated filter plate forms a third filter layer, and the particle sizes of the quartz sand in the first filter layer, the second filter layer and the third filter layer are sequentially reduced.

5. The high-efficiency industrial pure water production system according to claim 3, wherein the quartz sand filter further comprises an overflow outlet pipe connected to the outlet end of the header pipe;

the overflow water outlet pipeline comprises a first pipe section communicated with the water outlet end of the water collecting pipe, a vertical ascending pipe section communicated with the tail end of the first pipe section, a V-shaped sand settling pipe section communicated with the tail end of the ascending pipe section, an S-shaped climbing pipe section communicated with the sand settling pipe section and a second pipe section communicated with the S-shaped climbing pipe section.

6. The high-efficiency industrial pure water production system according to claim 5, wherein the first pipe section is arranged obliquely, the first end of the first pipe section connected with the water collecting pipe is lower than the second end of the first pipe section connected with the vertical ascending pipe section, and the bottom of the first end of the first pipe section is provided with a first sand discharge port;

the V-shaped first top end of the sand setting pipe section is communicated with the tail end of the vertical ascending pipe section through an arc pipe section, and the V-shaped second top end of the sand setting pipe section is communicated with the bottom end of the S-shaped climbing pipe section; and a second sand discharge port is formed in the V-shaped bottom end of the sand settling pipe section.

7. The high-efficiency industrial pure water production system according to claim 6, wherein a first arc-shaped sand-blocking sheet is arranged on the inner wall of the arc-shaped pipe section;

the S-shaped climbing pipe section is obliquely arranged, and a plurality of second arc-shaped sand-blocking sheets are arranged on the inner wall of the S-shaped climbing pipe section at intervals;

the second arc-shaped sand preventing sheets are arranged in a downward inclined mode, namely the upper ends of the second arc-shaped sand preventing sheets are connected with the inner wall of the S-shaped climbing pipe section, and the lower ends of the second arc-shaped sand preventing sheets are far away from the inner wall of the S-shaped climbing pipe section.

8. The high-efficiency industrial pure water production system according to claim 2, wherein the medicament adding device comprises a blending box, a turbine box arranged on the upper part of the blending box, a stirring impeller arranged inside the blending box, a driving turbine arranged in the turbine box and coaxial with the stirring impeller, and a medicament storage tank arranged on the blending box.

9. The high-efficiency industrial pure water production system according to claim 8, wherein a scale inhibitor is stored in the medicament storage tank, and the medicament storage tank is connected with the blending tank through a medicament pipeline;

the water inlet end of the turbine box is connected with the third water conveying pipe, and the water outlet end of the turbine box is connected to the blending box through a seventh water conveying pipe;

the water entering from the water inlet end of the turbine box flows into the mixing box through the water outlet end of the turbine box after passing through the driving turbine so as to drive the driving turbine to rotate, and the stirring impeller is driven to rotate by the driving turbine.

10. The high-efficiency industrial pure water production system according to claim 9, wherein a drug feeding device is arranged in the blending tank, and comprises a drug feeding pipe section communicated with the drug pipeline, a conical mixing pipe section connected to the lower end of the drug feeding pipe section, a water outlet ball connected to the lower end of the conical mixing pipe section, and a water feeding pipe section of which the first end is connected with the outer wall of the conical mixing pipe section and the second end is connected with the seventh water conveying pipe;

a plurality of water outlet through holes are formed in the outer wall of the water outlet ball body; the water outlet through hole is a conical hole, and the diameter of the water outlet through hole is gradually reduced from the inner wall of the water outlet ball body to the outside;

the first end of the water inlet pipe section is tangent to the outer wall of the conical mixing pipe section.

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