CN116621250B - High-efficiency energy-saving intelligent circulating water system based on full-flow optimization - Google Patents

Abstract

The application relates to the technical field of circulating water, and provides a high-efficiency energy-saving intelligent circulating water system based on full-flow optimization, which comprises a plurality of unit optimization treatment pipes; the unit optimizing treatment pipe is internally provided with a multi-stage water quality optimizing piece, and the multi-stage water quality optimizing piece consists of a plurality of sections of unit water quality adjusting pipes; the unit water quality adjusting pipe is provided with an inner water quality adjusting pipe; the inner water quality adjusting pipe is provided with a radial water adjusting frame; multiple sections of circulating water with different water qualities are processed by utilizing a plurality of unit optimizing processing pipes in mutually independent and accurate correspondence, so that the device is efficient and energy-saving; the radial water regulating frame inside the single unit optimizing treatment pipe is used for treating the water quality of the circulating water in the axial direction sequentially through the pipeline, so that the water quality of the circulating water is efficiently, comprehensively and uniformly optimized, the water quality detection accuracy of the circulating water is improved, the effect that the unit optimizing treatment pipes are used for treating the circulating water with different water qualities by proper dosage in respective single bodies is achieved, and the accurate, efficient and energy-saving intelligent full-flow optimization is achieved.

Description

High-efficiency energy-saving intelligent circulating water system based on full-flow optimization

Technical Field

The application relates to the technical field of circulating water, in particular to a high-efficiency energy-saving intelligent circulating water system based on full-flow optimization.

Background

Water is an important resource for all life including inorganic chemical combination and human beings, and is also an important resource in the aspects of development of industry and living demands; in order to cope with green recycling economy and achieve the purpose of saving water, circulating water is inoculated, and the circulating water mainly comprises two types of industry and household;

factors which mainly affect equipment in the operation of an industrial circulating water system are alkalinity, pH value and Cl ^- The comprehensive influence of factors such as oxygen content, hardness of circulating water, concentration multiple, mass propagation of microorganisms and the like, scaling or corrosion tendency is generated, and the safety and the operation efficiency of a circulating cooling system are both adversely affected; further, the circulating water needs to be treated in time;

at present, a plurality of water treatment methods are adopted, wherein one common method is to add a medicament into circulating water for treatment, because of the water source tightness of the circulating water and the water quality difference before and after the medicament is added to treat the water body, the water quality in the water system is uneven after the medicament is added to treat the water body, the medicament is uniformly added after the medicament passes through a monitor, the water system cannot be accurately treated at proper time according to different time periods, namely, the water system cannot be accurately positioned for relatively independent unit type treatment, and unnecessary resource waste is caused.

Based on the method, the application designs a high-efficiency energy-saving intelligent circulating water system based on full-flow optimization so as to solve the problems.

Disclosure of Invention

The application aims to solve the defects in the prior art: because the water source tightness of the circulating water and the equipment for adding the medicament to treat the water are also part of the circulating water system, the medicament is uniformly added after passing through the monitor, the relatively independent unit type treatment cannot be performed in a precise positioning manner, unnecessary resource waste is caused, and the high-efficiency energy-saving intelligent circulating water system based on full-flow optimization is provided.

The specific technical scheme is as follows: the high-efficiency energy-saving intelligent circulating water system based on full-flow optimization comprises a circulating water tank, a circulating water optimization assembly and a water quality on-line detection tube group, wherein the circulating water optimization assembly is assembled on the circulating water tank and provides the circulating water after optimization treatment for the circulating water tank; the water quality on-line detection tube set is assembled on the circulating water optimizing assembly and provides detected circulating water for the circulating water optimizing assembly; the circulating water optimizing assembly comprises a chemical adding frame, a circulating water optimizing treatment pipe group and a circulating water distributing pipe group; the circulating water optimizing treatment pipe group comprises a plurality of unit optimizing treatment pipes which are independently arranged, are arranged in a plurality of rows and a plurality of columns, and are communicated with the circulating water pool through electromagnetic valves; the circulating water distribution pipe group comprises a plurality of circulating water distribution pipes which are independently arranged; the plurality of circulating water distribution pipes and the plurality of unit optimization treatment pipes are in one-to-one correspondence; the dosing rack is used for providing a plurality of unit optimizing treatment pipes with a medicament for treating water quality;

the unit optimizing treatment pipe is internally provided with a multi-stage water quality optimizing part, the multi-stage water quality optimizing part consists of a plurality of reinforcing connecting frames and a plurality of unit water quality adjusting pipes, and the reinforcing connecting frames and the unit water quality adjusting pipes are distributed in a cross array; the unit water quality adjusting pipe consists of a pipe body and an inner water quality adjusting pipe inserted in the pipe body, wherein the end of the inner water quality adjusting pipe is communicated with the pipe body; the inner water quality adjusting pipe comprises a radial water adjusting frame, the radial water adjusting frame is used for extracting circulating water in the inner water quality adjusting pipe at multiple points in the axial direction of the inner water quality adjusting pipe, radially adjusting the circulating water into a gap between the pipe body and the inner water quality adjusting pipe, and synchronously radially adjusting the circulating water in the gap into the inner water quality adjusting pipe;

one end of an inner water quality regulating pipe on one unit water quality regulating pipe in the multiple unit water quality regulating pipes is communicated with a radial regulating pipe on the other unit water quality regulating pipe and is discharged into a gap between the pipe body and the inner water quality regulating pipe;

in the process that a section of unit water quality regulating pipe independently regulates the water quality of circulating water by using an inner water quality regulating pipe, a radial water regulating frame is used for extracting circulating water in the inner water quality regulating pipe at multiple points in the axial direction of the inner water quality regulating pipe, radially regulating the circulating water into a gap between the pipe body and the inner water quality regulating pipe, and synchronously radially regulating the circulating water in the gap into the inner water quality regulating pipe; the method has the advantages that the optimization treatment of the water quality of the circulating water in the axial direction of the pipeline is realized, the mode that the stirring frame is additionally arranged in the traditional pipeline is avoided, and the stirring can only be transversely rotated and stirred on a certain transverse section, so that the optimization of the water quality adjustment of the circulating water is completed; after the water quality is monitored in real time through the water quality on-line detection tube group, a plurality of unit optimizing treatment tubes are used for finishing independent and accurate corresponding treatment of multiple circulating water sections of different water qualities through the circulating water distribution tube group, a radial water regulating frame inside a single unit optimizing treatment tube is used for regulating and uniformly optimizing the circulating water quality in the axial direction of the inner water quality regulating tube, multiple points are formed by regulating and uniformly optimizing the circulating water quality in the axial sequential direction through pipelines, the circulating water quality is comprehensively and uniformly optimized, the circulating water quality detection accuracy is improved, and further, the effect that the unit optimizing treatment tubes are all treated with proper medicament in respective monomers is achieved, and the accurate, efficient and energy-saving intelligent full-flow optimization corresponding treatment of different water quality circulating water is achieved.

The technical scheme of the application is further described as follows:

in one of the technical schemes of the application, the water quality online detection tube group comprises a primary water quality online detection tube and a secondary water quality online detection tube, and the primary water quality online detection tube and the secondary water quality online detection tube are detachably connected through a connecting flange; the online detection tube for the primary water quality and the online detection tube for the secondary water quality are provided with a plurality of detection points in an array mode, and each detection point is provided with a pH value online detector, an ORP online detector, an electrical conductivity online detector and a sensor detection head of a medicament concentration online detector.

In one of the technical schemes of the application, the dosing frame comprises a reinforcing frame, a dosing tank and a supporting frame; the reinforcing frame is arranged on the circulating water optimizing treatment pipe group and used for supporting the supporting frame on the basis of binding the circulating water optimizing treatment pipe group; the support frame is provided with a support plate which is additionally arranged at the top of the reinforcing frame through a mounting plate; the medicine adding tanks are provided with a plurality of medicine adding tanks, and respectively and correspondingly provided with different medicines; the dosing tank is arranged on the supporting plate, and is correspondingly connected with a connecting hose which is correspondingly connected to the unit optimizing treatment pipe.

In one of the technical schemes of the application, the circulating water distribution pipe group also comprises a circulating water distribution main pipe, and the circulating water distribution main pipe is connected to the water quality on-line detection pipe group through a solenoid valve pipe B; the circulating water distribution pipes are arranged around the circulating water distribution main pipe, one end of each circulating water distribution pipe, which is far away from the circulating water distribution main pipe, is connected with a solenoid valve pipe A, and the solenoid valve pipe A is communicated with the unit optimizing treatment pipe.

In one of the technical schemes of the application, the unit optimizing treatment pipe comprises an outer fixing shell, wherein the outer fixing shell consists of two semi-fixing shells which are mutually buckled, and the two semi-fixing shells are matched with screws through locking plates at two sides of the outer fixing shell to finish locking.

In one of the technical schemes of the application, the inner water quality adjusting pipe also comprises a power bearing frame and an inner water quality adjusting pipe body, and the radial water quality adjusting frame is spirally and slidingly connected with the inner water quality adjusting pipe body; the power receiving frame is rotatably connected to the inner water quality adjusting pipe body and is in power transmission connection with the radial water adjusting frame; the outside of the power receiving frame is provided with a baffle plate, and the baffle plate divides a gap between the radial adjusting pipe body and the inner water quality adjusting pipe into a water passing cavity and a sealing cavity.

In a further aspect of the present application, the power receiving rack includes a drive ring, an outer seal bearing ring, an inner seal bearing ring, and a gear ring; the gear ring is fixed on the driving ring, the gear ring and the driving ring are coaxially arranged, a gear is meshed on the gear ring, and the gear is fixed on an output shaft of the motor; the motor and the gear ring are both positioned in the sealing cavity; the radial water regulating frame is connected to the driving ring in a power transmission way; the driving ring is rotationally connected to the inner water quality adjusting pipe body through the inner sealing bearing ring, and is rotationally connected to the partition plate through the outer sealing bearing ring.

In the optimized scheme of the application, the inner water quality adjusting pipe body comprises a connecting pipe body A, a spiral connecting plate and a connecting pipe body B, wherein the spiral connecting plate is connected between the connecting pipe body A and the connecting pipe body B, and a spiral groove is formed on the spiral connecting plate body in a spiral manner; the radial water regulating frame is spirally and slidingly connected on the spiral groove.

The radial water regulating frame comprises a spiral plate which is spirally and slidingly connected to the spiral groove; a plurality of radial water regulating pipes distributed in an array are spirally distributed on the spiral plate.

The radial water regulating pipe comprises a radial water regulating pipe and a radial water regulating pipe, and a radial water regulating pipe at the side edge of the radial water regulating pipe is provided with a water inlet; the radial water regulating outlet pipe and the water inlet hole are communicated to the inside of the inner water quality regulating pipe body through the spiral plate; the inside of the radial water mixing and discharging pipe is provided with a pump A for discharging water, and the inside of the water inlet hole is provided with a pump B for feeding water.

Compared with the prior art, the application has the beneficial effects that:

the circulating water is guided into the unit optimizing treatment pipes, and the chemical adding rack is used for providing chemicals for treating the quality of the circulating water for the unit optimizing treatment pipes; the multi-section circulating water is treated by the unit optimizing treatment pipes independently, so that mutual interference is avoided, and meanwhile, the water quality optimizing treatment time is reserved in a sequential treatment mode among the unit optimizing treatment pipes, so that the circulating water is optimally treated without stopping;

the water quality is monitored in real time by using the water quality online detection tube group, and after the water quality online detection tube group is correspondingly segmented into a plurality of sections of circulating water, the water quality online detection tube group is correspondingly and respectively led into a plurality of unit optimizing treatment tubes, so that the plurality of unit optimizing treatment tubes are mutually independent and accurately correspondingly treat the plurality of sections of circulating water with different water qualities, the plurality of unit optimizing treatment tubes are realized to accurately and correspondingly treat the plurality of sections of circulating water with different water qualities in a proper medicine amount, and the waste caused by excessive medicine input is avoided;

in the process that a section of unit water quality regulating pipe independently regulates the water quality of circulating water by using an inner water quality regulating pipe, a radial water regulating frame is used for extracting circulating water in the inner water quality regulating pipe at multiple points in the axial direction of the inner water quality regulating pipe, radially regulating the circulating water into a gap between the pipe body and the inner water quality regulating pipe, and synchronously radially regulating the circulating water in the gap into the inner water quality regulating pipe; the method has the advantages that the optimization treatment of the water quality of the circulating water in the axial direction of the pipeline is realized, the mode that the stirring frame is additionally arranged in the traditional pipeline is avoided, and the stirring can only be transversely rotated and stirred on a certain transverse section, so that the optimization of the water quality adjustment of the circulating water is completed; so as to facilitate the follow-up accurate and efficient energy-saving treatment of the circulating water;

after the water quality is monitored in real time through the water quality on-line detection tube group, a plurality of unit optimizing treatment tubes are used for finishing independent and accurate corresponding treatment of multiple sections of circulating water with different water qualities through the circulating water distribution tube group, a radial water regulating frame inside a single unit optimizing treatment tube is used for regulating and optimizing the water quality of the circulating water in the axial direction of the inner water quality regulating tube at multiple points, so that the circulating water quality is uniformly and uniformly regulated in the axial sequential direction through the pipeline, the circulating water quality is comprehensively and uniformly formed, the circulating water quality detection accuracy is improved, and further, the effect that the unit optimizing treatment tubes are all treated with proper medicament dosage in respective single bodies is realized, and the accurate, efficient and energy-saving intelligent full-flow optimization corresponding treatment of the circulating water with different water qualities is achieved;

the method comprises the steps that a primary water quality online detection pipe and a secondary water quality online detection pipe perform double multi-point monitoring on the water quality of circulating water passing through a pipeline in the axial direction of the pipeline through a pH value online detector, an ORP online detector, an electric conductivity online detector and a sensor detection head of a medicament concentration online detector at a plurality of detection points on the respective main bodies, and feed the water quality of the circulating water passing through the pipeline at corresponding time points back to an external computer, so that the water quality of the circulating water flowing through different positions in the pipeline at different time periods is detected approximately, the detected circulating water is segmented into a plurality of sections by using a circulating water distribution pipe in cooperation with the subsequent circulating water distribution pipe, and the multi-section circulating water is correspondingly and respectively led into a plurality of unit optimization treatment pipes; the water quality condition of the circulating water in each unit optimizing treatment pipe is further accurately known by utilizing a plurality of detection points arranged in the unit optimizing treatment pipe, and the aim of carrying out accurate, efficient and energy-saving intelligent full-flow optimization corresponding treatment on different water quality circulating water by matching with a dosing rack according to each proper dosing is achieved;

the motor is utilized to rotate left and right periodically to drive the spiral plate on the radial water regulating frame to slide in the spiral groove on the inner water quality regulating pipe body, so that the radial water regulating pipes distributed in multiple arrays are driven to rotate radially to regulate circulating water in different radial directions, circulating water in the inner water quality regulating pipe body is regulated at multiple points in the axial direction of the inner water quality regulating pipe body, uniform optimization treatment of circulating water quality is realized in multiple directions, and the traditional stirring frame additionally arranged in a pipeline is prevented from being stirred in a transverse section by transverse rotation.

Drawings

FIG. 1 is a schematic diagram of a full-flow optimization-based efficient energy-saving intelligent circulating water system;

FIG. 2 is a schematic diagram of the structure of the water quality online detection tube set of the present application;

FIG. 3 is a schematic diagram of an assembled structure of the circulating water reservoir and circulating water optimizing assembly of the present application;

FIG. 4 is a schematic view showing the assembled structure of the circulating water optimizing treatment pipe group and the circulating water distribution pipe group of the present application;

FIG. 5 is a schematic view showing the construction of a circulating water distribution pipe group according to the present application;

FIG. 6 is a schematic view of a unit optimizing process tube according to the present application;

FIG. 7 is a schematic view of a multistage water quality optimizing member according to the present application;

FIG. 8 is a schematic view of a unit water quality adjusting pipe according to the present application;

FIG. 9 is a cross-sectional view of the unit water quality adjusting pipe of FIG. 8;

FIG. 10 is a schematic view of the structure of the inner water quality adjusting pipe in the application;

FIG. 11 is a schematic view of the structure of the inner water quality adjusting pipe body in the application;

FIG. 12 is a schematic view of a radial water dispenser according to the present application;

FIG. 13 is an explanatory view of the internal water quality adjusting pipe for adjusting the water quality in the present application.

In the drawings, the list of components represented by the various numbers is as follows:

100-a circulating water tank; 200-a circulating water optimizing assembly; 210-adding a medicament rack; 211-reinforcing frames, 212-dosing tanks and 213-supporting frames; 220-circulating water optimizing treatment pipe group; 230-a circulating water distribution pipe group; 231-solenoid valve pipe a, 232-circulation water distribution pipe, 233-circulation water distribution main pipe, 234-solenoid valve pipe B; 240-unit optimizing process tube; 241-outer fixed shell, 242-locking plate, 243-multistage water quality optimizing piece; 2431-reinforcing connecting frame, 2432-unit water quality regulating pipe, 2433-pipe body and 2434-inner water quality regulating pipe; 24341-radial water regulating rack (243411-spiral plate, 243412-radial water regulating pipe, 243413-radial water regulating pipe, 243414-radial water regulating pipe, 243415-water inlet hole), 24342-partition plate, 24343-power receiving rack (243431-outer sealing bearing ring, 243432-driving ring, 243433-inner sealing bearing ring, 243434-gear ring), 24344-inner water regulating pipe body (243441-connecting pipe body a, 243442-spiral groove, 243443-spiral connecting plate, 243444-connecting pipe body B); 300-water quality on-line detection tube group; 310-primary water quality on-line detection pipe, 320-connecting flange and 330-secondary water quality on-line detection pipe.

Description of the embodiments

The present application will be described in further detail with reference to specific embodiments in order to make the objects, technical solutions and advantages of the present application more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the application. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

Inventive example 1

Please refer to fig. 1: the utility model provides a high-efficient energy-saving wisdom circulating water system based on full flow optimization, includes circulating water pond 100, circulating water optimizing assembly 200 and quality of water on-line measuring nest 300, circulating water optimizing assembly 200 assembles on circulating water pond 100 to for circulating water pond 100 provides the circulating water after optimizing treatment; the water quality on-line detecting tube set 300 is assembled on the circulating water optimizing assembly 200 and provides the circulating water after detection for the circulating water optimizing assembly 200;

thus, the method comprises the steps of; the circulating water firstly enters the water quality on-line detection tube set 300, the water quality is monitored in real time by the water quality on-line detection tube set 300, then is led into the circulating water optimizing assembly 200, the circulating water is subjected to water quality optimizing treatment by the circulating water optimizing assembly 200, and after the water quality reaches the standard, the circulating water is led into the circulating water tank 100; finally, the optimized circulating water is mixed by utilizing a plurality of groups of stirring frames arranged in the circulating water tank 100, so that the quality of the circulating water is uniform;

please refer to fig. 3-5: the circulating water optimizing assembly 200 includes a chemical adding rack 210, a circulating water optimizing treatment pipe group 220 and a circulating water distributing pipe group 230;

the circulating water optimizing treatment tube group 220 comprises a plurality of unit optimizing treatment tubes 240 which are independently arranged, and the unit optimizing treatment tubes 240 are arranged in a plurality of rows and a plurality of columns and are communicated with the circulating water pool 100 through electromagnetic valves;

the circulating water distribution pipe group 230 includes a plurality of circulating water distribution pipes 232 independently provided; the plurality of circulating water distribution pipes 232 and the plurality of unit optimizing pipes 240 are in one-to-one correspondence;

the dosing frame 210 is used to provide a plurality of unit optimizing treatment tubes 240 with a treatment agent for water quality;

therefore, the circulating water introduced into the circulating water optimizing unit 200 is segmented into a plurality of segments by the circulating water distributing pipe 232, and is respectively introduced into the plurality of unit optimizing pipes 240, and then the chemical adding rack 210 is started to provide chemicals for treating the quality of the circulating water for the plurality of unit optimizing pipes 240; the multiple-section circulating water is treated by the multiple unit optimizing treatment pipes 240 independently of each other, so that mutual interference is avoided, meanwhile, the water quality optimizing treatment time is reserved in a sequential treatment mode among the multiple unit optimizing treatment pipes 240, and the circulating water is optimized and treated without stopping;

and after the water quality is monitored in real time by combining the water quality on-line detection tube set 300, the water quality is led into the circulating water optimizing assembly 200, so that the multiple-section circulating water with different water qualities is accurately and correspondingly treated by the multiple unit optimizing treatment tubes 240 in mutually independent mode, the multiple-section circulating water with different water qualities is accurately and correspondingly treated by the multiple unit optimizing treatment tubes 240 in proper medicament dosage, and the waste caused by excessive medicament input is avoided;

the mode to traditional pipeline delivery water is for under certain pressure, and the place ahead water is promoted to the rear water and is carried forward, and current mode of installing the stirring frame additional in the pipeline also can only transversely rotate the stirring on a certain horizontal cross-section, accomplishes circulating water quality of water and transfers all optimizing, and can't accomplish the circulating water quality of water to transfer all optimizing process on the pipeline in epaxial sequential direction, causes the poor problem of circulating water quality of water detection accuracy, and the special proposal:

please refer to fig. 6-10, 13: the unit optimizing treatment pipe 240 is internally provided with a multi-stage water quality optimizing member 243, the multi-stage water quality optimizing member 243 consists of a plurality of sections of reinforcing connecting frames 2431 and a plurality of sections of unit water quality adjusting pipes 2432, and the plurality of sections of reinforcing connecting frames 2431 and the plurality of sections of unit water quality adjusting pipes 2432 are distributed in a cross array; the unit water quality adjusting pipe 2432 consists of a pipe body 2433 and an inner water quality adjusting pipe 2434 inserted in the pipe body 2433, wherein the end of the inner water quality adjusting pipe 2434 is communicated with the pipe body 2433; the inner water quality adjusting pipe 2434 comprises a radial water adjusting frame 24341, the radial water adjusting frame 24341 is used for extracting circulating water in the inner water quality adjusting pipe 2434 at multiple points in the axial direction of the inner water quality adjusting pipe 2434, radially adjusting the circulating water in the gap into a gap between the pipe body 2433 and the inner water quality adjusting pipe 2434, and synchronously adjusting the circulating water in the gap into the inner water quality adjusting pipe 2434 radially;

one end of an inner water quality regulating pipe 2434 on one unit water quality regulating pipe 2432 of the multiple unit water quality regulating pipes 2432 is communicated with the radial direction on the other unit water quality regulating pipe 2432 and is pulled out into a gap between the pipe body 2433 and the inner water quality regulating pipe 2434;

therefore, the circulating water after detection is led into the multistage water quality optimizing member 243 installed in the unit optimizing treatment pipe 240 by the circulating water distributing pipe 232, the circulating water firstly enters the inner water quality adjusting pipe 2434 on one section of the unit water quality adjusting pipe 2432, and is radially regulated out into the gap between the pipe body 2433 and the inner water quality adjusting pipe 2434 by the circulating water distributing pipe, and the circulating water in the gap enters the inner water quality adjusting pipe 2434 on the other section of the unit water quality adjusting pipe 2432 again, so that the multistage water quality optimizing member 243 sequentially adjusts the water quality for a plurality of times by using the plurality of sections of the unit water quality adjusting pipes 2432;

in the process that a section of unit water quality regulating pipe 2432 independently regulates the water quality of circulating water by using an inner water quality regulating pipe 2434, circulating water in the inner water quality regulating pipe 2434 is extracted at multiple points in the axial direction of the inner water quality regulating pipe 2434 by using a radial water regulating frame 24341, radially regulated out into a gap between a pipe body 2433 and the inner water quality regulating pipe 2434, and the circulating water in the gap is synchronously regulated into the inner water quality regulating pipe 2434 in the radial direction; the method realizes the uniform adjustment and optimization treatment of the water quality of the circulating water in the axial direction of the pipeline (particularly, the demonstration diagram of the water quality adjustment pipe in fig. 13 can be referred to in detail), avoids the traditional mode of adding a stirring rack in the pipeline, and can only carry out transverse rotation stirring on a certain transverse section, thereby completing the uniform adjustment and optimization of the water quality of the circulating water; so as to facilitate the follow-up accurate and efficient energy-saving treatment of the circulating water;

after the water quality is monitored in real time through the water quality on-line detection tube set 300, a plurality of unit optimizing treatment tubes 240 are utilized to finish the multi-section circulating water which is mutually independent and accurately corresponds to different water qualities, a radial water regulating frame 24341 inside a single unit optimizing treatment tube 240 is utilized to uniformly regulate and optimize the water quality of the circulating water in the axial direction of an inner water quality regulating tube 2434, multiple points are formed by sequentially regulating and uniformly optimizing the water quality of the circulating water in the axial direction, the water quality of the circulating water is comprehensively and uniformly optimized, the water quality detection accuracy of the circulating water is improved, and further, the effect that the unit optimizing treatment tubes 240 are all used for treating the circulating water with different water qualities by proper medicament amount in respective single bodies is realized.

Inventive example 2

Please refer to fig. 1 and 2: the water quality online detection tube set 300 comprises a primary water quality online detection tube 310 and a secondary water quality online detection tube 330, wherein the primary water quality online detection tube 310 and the secondary water quality online detection tube 330 are detachably connected through a connecting flange 320;

the main bodies of the primary water quality online detection pipe 310 and the secondary water quality online detection pipe 330 are internally provided with a plurality of detection points in an array, and each detection point is provided with a pH value online detector, an ORP online detector, an electric conductivity online detector and a sensor detection head of a medicament concentration online detector.

The pH value online detector, the ORP online detector, the conductivity online detector and the medicament concentration online detector are all of the prior art, the detailed structure of the pH value online detector, the ORP online detector, the conductivity online detector and the medicament concentration online detector can be known from the existing literature journal, and the pH value online detector, the ORP online detector, the conductivity online detector and the medicament concentration online detector can be directly purchased in the market or can be composed by purchasing parts in the market; which are not intended to be protected by the present application and are not shown in detail in the accompanying drawings.

Therefore, the primary water quality online detection pipe 310 and the secondary water quality online detection pipe 330 perform dual multi-point monitoring on the water quality of circulating water passing through the pipeline in the axial direction through the pH value online detector, the ORP online detector, the conductivity online detector and the sensor detection head of the medicament concentration online detector at a plurality of detection points on the respective main bodies, and feed the water quality of the circulating water flowing through the pipeline at the corresponding time points back to an external computer, so as to roughly detect the water quality of the circulating water flowing through different positions in the pipeline at different time periods, segment the detected circulating water into a plurality of sections by using the circulating water distribution pipe 232 in cooperation with the subsequent use, and correspondingly guide the circulating water into the plurality of unit optimization treatment pipes 240 respectively; and then, the water quality condition of the circulating water in each unit optimizing treatment pipe 240 is further accurately known by utilizing a plurality of detection points arranged in the unit optimizing treatment pipe 240, so that the accurate, efficient and energy-saving intelligent full-flow optimization corresponding treatment of different water quality circulating water is realized by matching the dosing frame 210 with each proper dosing amount.

Example 3 of the application

Please refer to fig. 3: the dosing frame 210 comprises a reinforcing frame 211, a dosing tank 212 and a supporting frame 213;

the reinforcement frame 211 is erected on the circulating water optimizing treatment pipe group 220 and is used for supporting the supporting frame 213 on the basis of binding the circulating water optimizing treatment pipe group 220; the support frame 213 is provided with a support plate which is additionally arranged at the top of the reinforcing frame 211 through a mounting plate;

the medicine adding tanks 212 are provided with a plurality of medicine adding tanks, and respectively and correspondingly provided with different medicines; the medicine feeding tank 212 is installed on the supporting plate, and the medicine feeding tank 212 is correspondingly connected with a connection hose, and the connection hose is correspondingly connected to the unit optimizing process pipe 240.

Inventive example 4

Please refer to fig. 4 and 5: the circulating water distribution pipe group 230 further comprises a circulating water distribution main pipe 233, and the circulating water distribution main pipe 233 is connected to the water quality online detection pipe group 300 through a solenoid valve pipe B234;

a plurality of independently installed circulating water distribution pipes 232 are installed around the circulating water distribution main pipe 233, and the circulating water distribution pipes 232 are connected with a solenoid valve pipe a231 at one end far from the circulating water distribution main pipe 233, and the solenoid valve pipe a231 is connected to the unit optimizing process pipe 240.

Inventive example 5

Please refer to fig. 6: the unit optimizing treatment pipe 240 comprises an outer fixing shell 241, wherein the outer fixing shell 241 is composed of two semi-fixing shells which are buckled with each other, and the two semi-fixing shells are matched with screws through locking plates 242 at two sides of the outer fixing shell to complete locking.

Inventive example 6

Please refer to fig. 9 and 10: the inner water quality adjusting pipe 2434 further comprises a power bearing frame 24343 and an inner water quality adjusting pipe 24344, and the radial water adjusting frame 24341 is spirally and slidingly connected to the inner water quality adjusting pipe 24344;

the power receiving frame 24343 is rotatably connected to the inner water quality adjusting pipe 24344, and the power receiving frame 24343 is in power transmission connection with the radial water adjusting frame 24341; the outside of the power receiving frame 24343 is provided with a baffle 24342, and the baffle 24342 divides a clearance between the radial adjusting pipe 2433 and the inner water quality adjusting pipe 2434 into a water passing cavity and a sealing cavity.

Inventive example 7

Please refer to fig. 10: the power receiving rack 24343 includes a drive ring 243432, an outer seal race 243431, an inner seal race 243433, and a gear ring 243434;

the gear ring 243434 is fixed on the driving ring 243432, the gear ring 243434 and the driving ring 243432 are coaxially arranged, a gear is meshed with the gear ring 243434, and the gear is fixed on an output shaft of the motor; the motor and the gear ring 243434 are both in a sealed cavity; the radial water diversion frame 24341 is connected to the driving ring 243432 in a power transmission manner;

the drive ring 243432 is rotatably coupled to the inner water quality control tube 24344 by an inner seal race 243433 and the drive ring 243432 is rotatably coupled to the spacer 24342 by an outer seal race 243431.

Therefore, the motor is started, and the gear ring 243434 is driven to rotate left and right periodically by the motor reciprocating rotating shaft, so that the radial water regulating frame 24341 is driven to slide on the inner water quality regulating pipe 24344 in a spiral manner by the driving ring 243432.

Inventive example 8

Please refer to fig. 11: the inner water quality adjusting pipe 24344 comprises a connecting pipe A243441, a spiral connecting plate 243443 and a connecting pipe B243444, wherein the spiral connecting plate 243443 is connected between the connecting pipe A243441 and the connecting pipe B243444, and a spiral groove 243442 is formed on the spiral connecting plate 243443 in a spiral manner;

the radial water diversion frame 24341 is spirally and slidingly connected on the spiral groove 243442.

Inventive example 9

Please refer to fig. 10 and 12: the radial water diversion frame 24341 comprises a spiral plate 243411, and the spiral plate 243411 is spirally and slidingly connected on the spiral groove 243442; a plurality of radial water pipes 243412 distributed in an array are spirally distributed on the spiral plate 243411.

Therefore, the motor is utilized to rotate left and right periodically to drive the spiral plate 243411 on the radial water regulating frame 24341 to slide in the spiral groove 243442 on the inner water quality regulating pipe 24344 in a spiral manner, so that the radial water regulating pipes 243412 which are distributed in a plurality of arrays are driven to rotate radially to regulate circulating water in different radial directions, the circulating water in the inner water quality regulating pipe 24344 is regulated at multiple points in the axial direction of the inner water quality regulating pipe 24344, the uniform regulation and optimization treatment of the circulating water quality in multiple directions is realized, and the mode of additionally installing the stirring frame in a traditional pipeline is avoided, and the stirring can only be performed in a transverse rotation manner on a certain transverse section.

Example 10 of the application

Please refer to fig. 10 and 12: the radial water diversion pipe 243412 comprises a radial water diversion pipe 243413 and a radial water diversion pipe 243414, and a radial water diversion pipe 243414 on the side of the radial water diversion pipe 243413 is provided with a water inlet 243415;

the radial water regulating outlet pipe 243413 and the water inlet holes 243415 are communicated with the inside of the inner water quality regulating pipe 24344 through the spiral plate 243411; the radial water outlet pipe 243413 is internally provided with a pump A for water outlet, and the water inlet 243415 is internally provided with a pump B for water inlet.

The working principle of the application is as follows: the circulating water firstly enters the water quality on-line detection tube set 300, the water quality is monitored in real time by the water quality on-line detection tube set 300, then is led into the circulating water optimizing assembly 200, the circulating water is subjected to water quality optimizing treatment by the circulating water optimizing assembly 200, and after the water quality reaches the standard, the circulating water is led into the circulating water tank 100; finally, the optimized circulating water is mixed by utilizing a plurality of groups of stirring frames arranged in the circulating water tank 100, so that the quality of the circulating water is uniform; the circulating water introduced into the circulating water optimizing assembly 200 is segmented into a plurality of sections by the circulating water distributing pipe 232, and is correspondingly introduced into the unit optimizing treatment pipes 240 respectively, and then the chemical adding rack 210 is started to provide chemicals for treating the quality of the circulating water for the unit optimizing treatment pipes 240; the multiple-section circulating water is treated by the multiple unit optimizing treatment pipes 240 independently of each other, so that mutual interference is avoided, meanwhile, the water quality optimizing treatment time is reserved in a sequential treatment mode among the multiple unit optimizing treatment pipes 240, and the circulating water is optimized and treated without stopping; and after the water quality is monitored in real time by combining the water quality on-line detection tube set 300, the water quality is led into the circulating water optimizing assembly 200, so that the multiple-section circulating water with different water qualities is accurately and correspondingly treated by the multiple unit optimizing treatment tubes 240 in mutually independent mode, and the multiple-section circulating water with different water qualities is accurately and correspondingly treated by the multiple unit optimizing treatment tubes 240 in proper medicament dosage; the circulating water after detection is led into the multistage water quality optimizing part 243 arranged in the unit optimizing treatment pipe 240 by the circulating water distributing pipe 232, the circulating water firstly enters the inner water quality adjusting pipe 2434 on one section of unit water quality adjusting pipe 2432, and is radially regulated out into a gap between the pipe body 2433 and the inner water quality adjusting pipe 2434 by the circulating water distributing pipe, and the circulating water in the gap enters the inner water quality adjusting pipe 2434 on the other section of unit water quality adjusting pipe 2432 again, so that the multistage water quality optimizing part 243 sequentially adjusts the water quality for a plurality of times by using the plurality of sections of unit water quality adjusting pipes 2432; in the process that a section of unit water quality regulating pipe 2432 independently regulates the water quality of circulating water by using an inner water quality regulating pipe 2434, circulating water in the inner water quality regulating pipe 2434 is extracted at multiple points in the axial direction of the inner water quality regulating pipe 2434 by using a radial water regulating frame 24341, radially regulated out into a gap between a pipe body 2433 and the inner water quality regulating pipe 2434, and the circulating water in the gap is synchronously regulated into the inner water quality regulating pipe 2434 in the radial direction; the method realizes the uniform adjustment and optimization treatment of the water quality of the circulating water in the axial direction of the pipeline (particularly, the demonstration diagram of the water quality adjustment pipe in fig. 13 can be referred to in detail), avoids the traditional mode of adding a stirring rack in the pipeline, and can only carry out transverse rotation stirring on a certain transverse section, thereby completing the uniform adjustment and optimization of the water quality of the circulating water;

after the water quality is monitored in real time through the water quality on-line detection tube set 300, a plurality of unit optimizing treatment tubes 240 are utilized to finish independent and accurate corresponding treatment of multiple circulating water of different water qualities through the circulating water distribution tube set 230, a radial water regulating frame 24341 inside a single unit optimizing treatment tube 240 is utilized to uniformly regulate and optimize the water quality of the circulating water in the axial direction of an inner water quality regulating tube 2434 at multiple points, so that the water quality of the circulating water is comprehensively and uniformly optimized, the water quality of the circulating water is improved, the water quality detection accuracy of the circulating water is improved, and further, the effect that the unit optimizing treatment tubes 240 are all optimized to treat the circulating water of different water qualities through proper medicament doses in respective monomers in an accurate, efficient and energy-saving intelligent whole-flow optimization manner is realized;

the primary water quality online detection pipe 310 and the secondary water quality online detection pipe 330 perform dual multi-point monitoring on the water quality of circulating water passing through the pipeline in the axial direction through the pH value online detector, the ORP online detector, the conductivity online detector and the sensor detection head of the medicament concentration online detector at a plurality of detection points on the respective main bodies, feed the water quality of the circulating water flowing through the pipeline at the corresponding time points back to an external computer, and roughly detect the water quality of the circulating water flowing through different positions in the pipeline at different time periods so as to segment the detected circulating water into a plurality of sections by matching with the circulating water distribution pipe 232 and correspondingly guide the circulating water into the plurality of unit optimization processing pipes 240 respectively; and then, the water quality condition of the circulating water in each unit optimizing treatment pipe 240 is further accurately known by utilizing a plurality of detection points arranged in the unit optimizing treatment pipe 240, so that the accurate, efficient and energy-saving intelligent full-flow optimization corresponding treatment of different water quality circulating water is realized by matching the dosing frame 210 with each proper dosing amount.

Finally, it should be noted that: the foregoing description is only illustrative of the preferred embodiments of the present application, and although the present application has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements or changes may be made without departing from the spirit and principles of the present application.

Claims (10)

1. The high-efficiency energy-saving intelligent circulating water system based on full-flow optimization comprises a circulating water tank, a circulating water optimization assembly and a water quality on-line detection tube group, wherein the circulating water optimization assembly is assembled on the circulating water tank and provides the circulating water after optimization treatment for the circulating water tank; the water quality on-line detection tube set is assembled on the circulating water optimizing assembly and provides detected circulating water for the circulating water optimizing assembly;

it is characterized in that the method comprises the steps of,

the circulating water optimizing assembly comprises a chemical adding frame, a circulating water optimizing treatment pipe group and a circulating water distributing pipe group;

the circulating water optimizing treatment pipe group comprises a plurality of unit optimizing treatment pipes which are independently arranged, are arranged in a plurality of rows and a plurality of columns, and are communicated with the circulating water pool through electromagnetic valves;

the circulating water distribution pipe group comprises a plurality of circulating water distribution pipes which are independently arranged; the plurality of circulating water distribution pipes and the plurality of unit optimization treatment pipes are in one-to-one correspondence;

the dosing rack is used for providing a plurality of unit optimizing treatment pipes with a medicament for treating water quality;

the unit optimizing treatment pipe is internally provided with a multi-stage water quality optimizing part, the multi-stage water quality optimizing part consists of a plurality of reinforcing connecting frames and a plurality of unit water quality adjusting pipes, and the reinforcing connecting frames and the unit water quality adjusting pipes are distributed in a cross array; the unit water quality adjusting pipe consists of a pipe body and an inner water quality adjusting pipe inserted in the pipe body, wherein the end of the inner water quality adjusting pipe is communicated with the pipe body; the inner water quality adjusting pipe comprises a radial water adjusting frame, the radial water adjusting frame is used for extracting circulating water in the inner water quality adjusting pipe at multiple points in the axial direction of the inner water quality adjusting pipe, radially adjusting the circulating water into a gap between the pipe body and the inner water quality adjusting pipe, and synchronously radially adjusting the circulating water in the gap into the inner water quality adjusting pipe;

the circulating water firstly enters the inner water quality regulating pipe on one unit water quality regulating pipe in the multi-section unit water quality regulating pipes, the circulating water is radially regulated out of a gap between the pipe body and the inner water quality regulating pipe through the inner water quality regulating pipe, and the circulating water in the gap enters the inner water quality regulating pipe on the other unit water quality regulating pipe, so that the multi-stage water quality optimizing part sequentially regulates the water quality of the circulating water for a plurality of times by utilizing the multi-section unit water quality regulating pipe.

2. The energy-efficient intelligent circulating water system based on full-process optimization according to claim 1, wherein,

the water quality online detection tube group comprises a primary water quality online detection tube and a secondary water quality online detection tube, and the primary water quality online detection tube and the secondary water quality online detection tube are detachably connected through a connecting flange;

the online detection tube for the primary water quality and the online detection tube for the secondary water quality are provided with a plurality of detection points in an array mode, and each detection point is provided with a pH value online detector, an ORP online detector, an electrical conductivity online detector and a sensor detection head of a medicament concentration online detector.

3. The energy-efficient intelligent circulating water system based on full-process optimization according to claim 1, wherein,

the dosing frame comprises a reinforcing frame, a dosing tank and a supporting frame;

the reinforcing frame is arranged on the circulating water optimizing treatment pipe group and used for supporting the supporting frame on the basis of binding the circulating water optimizing treatment pipe group; the support frame is provided with a support plate which is additionally arranged at the top of the reinforcing frame through a mounting plate;

the medicine adding tanks are provided with a plurality of medicine adding tanks, and respectively and correspondingly provided with different medicines; the dosing tank is arranged on the supporting plate, and is correspondingly connected with a connecting hose which is correspondingly connected to the unit optimizing treatment pipe.

4. The energy-efficient intelligent circulating water system based on full-process optimization according to claim 1, wherein,

the circulating water distribution pipe group also comprises a circulating water distribution main pipe, and the circulating water distribution main pipe is connected to the water quality online detection pipe group through an electromagnetic valve pipe B;

the circulating water distribution pipes are arranged around the circulating water distribution main pipe, one end of each circulating water distribution pipe, which is far away from the circulating water distribution main pipe, is connected with a solenoid valve pipe A, and the solenoid valve pipe A is communicated with the unit optimizing treatment pipe.

5. The full-flow optimization-based efficient energy-saving intelligent circulating water system is characterized in that the unit optimization treatment pipe comprises an outer fixing shell, wherein the outer fixing shell consists of two semi-fixing shells which are mutually buckled, and the two semi-fixing shells are matched with screws through locking plates at two sides of the outer fixing shell to finish locking.

6. The energy-efficient intelligent circulating water system based on full-process optimization according to claim 1, wherein,

the inner water quality adjusting pipe also comprises a power receiving frame and an inner water quality adjusting pipe body, and the radial water adjusting frame is spirally and slidingly connected to the inner water quality adjusting pipe body;

the power receiving frame is rotatably connected to the inner water quality adjusting pipe body and is in power transmission connection with the radial water adjusting frame; the outside of the power receiving frame is provided with a baffle plate, and the baffle plate divides a gap between the radial adjusting pipe body and the inner water quality adjusting pipe into a water passing cavity and a sealing cavity.

7. The energy-efficient intelligent circulating water system based on full-process optimization of claim 6, wherein,

the power bearing frame comprises a driving ring, an outer sealing bearing ring, an inner sealing bearing ring and a gear ring;

the gear ring is fixed on the driving ring, the gear ring and the driving ring are coaxially arranged, a gear is meshed on the gear ring, and the gear is fixed on an output shaft of the motor; the motor and the gear ring are both positioned in the sealing cavity; the radial water regulating frame is connected to the driving ring in a power transmission way;

the driving ring is rotationally connected to the inner water quality adjusting pipe body through the inner sealing bearing ring, and is rotationally connected to the partition plate through the outer sealing bearing ring.

8. The energy-efficient intelligent circulating water system based on full-process optimization of claim 7, wherein,

the inner water quality adjusting pipe body comprises a connecting pipe body A, a spiral connecting plate and a connecting pipe body B, wherein the spiral connecting plate is connected between the connecting pipe body A and the connecting pipe body B, and a spiral groove is formed on the spiral connecting plate body in a spiral mode;

the radial water regulating frame is spirally and slidingly connected on the spiral groove.

9. The full-flow optimization-based efficient energy-saving intelligent circulating water system is characterized in that the radial water regulating frame comprises a spiral plate which is in spiral sliding connection with a spiral groove; a plurality of radial water regulating pipes distributed in an array are spirally distributed on the spiral plate.

10. The energy-efficient intelligent circulating water system based on full-process optimization according to claim 9, wherein,

the radial water regulating pipe comprises a radial water regulating pipe and a radial water regulating pipe, and a radial water regulating pipe at the side edge of the radial water regulating pipe is provided with a water inlet;

the radial water regulating outlet pipe and the water inlet hole are communicated to the inside of the inner water quality regulating pipe body through the spiral plate; the inside of the radial water mixing and discharging pipe is provided with a pump A for discharging water, and the inside of the water inlet hole is provided with a pump B for feeding water.