CN114660253A - Online pollution source detection concurrent data processing method and system for enterprise technical service - Google Patents

Abstract

The application relates to a pollution source online detection concurrent data processing method and system for enterprise technical service, wherein the system comprises a storage module, an acquisition module, a processing module and a sending module, wherein a monitoring data packet of the acquisition module is acquired by a sampling device; the sampling device comprises a sampling pipeline, a water distribution pump and water online detection equipment, wherein the sampling pipeline is provided with a sampling port and a sampling port, the sampling pipeline is connected with a sampling main pipe at the sampling port, and the sampling main pipe is communicated with the water distribution pump and the water online detection equipment; be equipped with in the sample pipeline and switch the frame and be used for the drive to switch the gliding driving piece of frame, switch and be equipped with in proper order on the frame and filter and be used for the recoil mechanism with the butt joint of sampling house steward, the sample pipeline both sides all are equipped with and are used for holding recoil mechanism or filter holding chamber. This application has the effect that can ensure sampling device's monitoring data's accuracy.

Description

Online pollution source detection concurrent data processing method and system for enterprise technical service

Technical Field

The application relates to the technical field of pollution source online detection, in particular to a pollution source online detection concurrent data processing method and system for enterprise technical service.

Background

In recent years, along with the increase of population, the rapid development of industrial and agricultural production and urban construction, the waste amount of each river basin is continuously increased year by year, the exceeding rate of the water quality of the provincial section of the river basin is also in an increasing trend, particularly along with the economic development, the discharge amount of waste water of a plurality of industrial cities is large, the serious pollution of surface water of the cities is caused, and huge hidden dangers are brought to the life health of people. At present, in the process of treating sewage environmental pollution, the aim of controlling the over-standard sewage discharge is achieved mainly in a mode of carrying out on-line monitoring on the sewage discharge of a heavy-end enterprise.

Chinese patent with publication number CN112596899A in the related art proposes a pollution source on-line monitoring concurrent data processing method, system and storage medium, wherein the method comprises obtaining a ratio table of a plurality of sub-servers and a monitoring data packet of a current key pollution enterprise, and detecting data in the monitoring data packet; if the pollution source monitoring data contains the environmental quality monitoring data, distributing the electricity consumption data and the environmental quality monitoring data according to the proportion table, the first corresponding relation and the second corresponding relation, and sending the electricity consumption data and the environmental quality monitoring data to corresponding sub-servers; and if the pollution source monitoring data does not contain the environmental quality monitoring data, distributing the electricity utilization data in the monitoring data packet according to the ratio table and the first corresponding relation, and sending the electricity utilization data to the corresponding sub-servers. The system comprises a storage module, an acquisition module, a processing module and a sending module.

Chinese patent CN111060668A in related art proposes an online water quality monitoring and pretreatment device and a monitoring and pretreatment method thereof, wherein the treatment device comprises: the sampling device comprises a sampling pipeline I, a sampling pipeline II and a sewage backflow pipeline; the sedimentation filtering device comprises a sedimentation water tank and an original sample water tank, and a water distribution pump is arranged between the sedimentation water tank and the original sample water tank; and a water on-line detection device.

The related art described above has the following drawbacks: because sampling device sets up in the sewage mostly, after taking a sample many times, remain more impurity in the sampling tube easily, if long-time not clear up, can influence follow-up water quality monitoring data's precision.

Disclosure of Invention

In order to solve the problem that monitoring data is inaccurate due to the fact that water quality is not timely cleaned in online monitoring, the application provides a method and a system for online detection and concurrent data processing of a pollution source for enterprise technical service.

The first aspect of the application provides a pollution source online detection concurrent data processing system for enterprise technical service, which adopts the following technical scheme:

a pollution source online detection concurrent data processing system for enterprise technical service comprises a storage module, an acquisition module, a processing module and a sending module, wherein a monitoring data packet of the acquisition module is acquired by a sampling device;

the sampling device comprises a sampling pipeline, a water distribution pump and water online detection equipment, wherein the sampling pipeline is provided with a sampling port and a sampling port, the sampling pipeline is connected with a sampling main pipe at the sampling port, and the sampling main pipe is communicated with the water distribution pump and the water online detection equipment;

a switching frame and a driving piece for driving the switching frame to slide along the direction orthogonal to the axial direction of the sampling pipeline are arranged in the sampling pipeline, a filtering piece and a backflushing mechanism for butting with the sampling main pipe are sequentially arranged on the switching frame, and accommodating cavities are formed in two sides of the sampling pipeline;

when the switching frame slides to the state that the filter pieces are aligned with the sampling main pipe, the recoil mechanism corresponds to one of the accommodating cavities;

when the switching frame slides to the state that the recoil mechanism is aligned with the sampling main pipe, the filter piece corresponds to the other accommodating cavity.

Furthermore, the backflushing mechanism comprises a backflushing main pipe fixedly connected to the switching frame, a movable pipe used for being in butt joint with the sampling main pipe is elastically arranged at one end, close to the sampling main pipe, of the backflushing main pipe, a plurality of backflushing heads which point to the inner wall of the sampling pipeline in an inclined mode are arranged on the switching frame, and the backflushing heads are communicated with the backflushing main pipe.

Furthermore, a baffle is fixedly connected in the backflushing header pipe, the movable pipe penetrates through the baffle and is in sliding sealing connection with the baffle, one end, far away from the backflushing head, of the movable pipe is communicated with a butt joint pipe used for being in butt joint with the sampling header pipe, the outer diameter of the butt joint pipe is larger than that of the movable pipe, and an elastic piece is arranged between the butt joint pipe and the baffle.

Further, the peripheral wall of one end of the abutting pipe close to the sampling main pipe is provided with a transition surface.

Furthermore, a partition plate is fixedly connected to the middle of the switching frame, and sealing parts are arranged on the switching frame and the partition plate on two sides of the sampling pipeline in the axial direction;

when the filter piece or the recoil mechanism is positioned in the corresponding accommodating cavity, the sealing piece on the partition plate is abutted against the inner wall of the accommodating cavity.

Furthermore, the accommodating cavity close to the filtering piece is connected with a sewage flushing pipe of which one end is connected with the water distribution pump, the accommodating cavity is also connected with a sewage draining pipe which is arranged opposite to the sewage flushing pipe, and a sewage draining valve is arranged on the sewage draining pipe.

Furthermore, the sampling pipeline is provided with a one-way stopping piece at the sampling port, and the one-way stopping piece only allows the medium to enter the sampling pipeline from the outside of the sampling pipeline.

Furthermore, the sampling pipeline is connected with a sewage collecting pipe on the side wall close to the one-way stopping piece, and a sewage collecting valve is arranged on the sewage collecting pipe.

Furthermore, the sampling main pipe is connected with a three-way pipe, one end of the three-way pipe is connected with the water distribution pump and is provided with a first electromagnetic valve, and the other end of the three-way pipe is connected with the water online detection equipment and is provided with a second electromagnetic valve.

The second aspect of the present application provides a method for processing pollution source online detection concurrent data for enterprise technical services, which adopts the following technical scheme:

a pollution source online detection concurrent data processing method for enterprise technical service comprises the following steps:

storing data, namely storing a preset ratio table, a preset first corresponding relation and a preset second corresponding relation through the storage module, wherein the ratio table comprises node information of a plurality of sub-servers at different time and corresponding utilization ratio proportional relations;

acquiring data, namely acquiring the proportional table, and acquiring a monitoring data packet of the current key polluted enterprise through the sampling device;

data processing, namely detecting the monitoring data packet through the processing module, judging whether the monitoring data packet contains environmental quality monitoring data or not, and distributing the electricity utilization data or the electricity data and the environmental quality monitoring data in the monitoring data packet according to the ratio table and the first corresponding relation or the second corresponding relation;

data transmission, namely transmitting the power consumption data and the environmental quality monitoring data distributed and processed by the processing module to corresponding sub-servers through a transmitting module so that the corresponding sub-servers can process part of the received power consumption data or part of the received power consumption data and part of the received environmental quality monitoring data;

after the sampling device acquires a primary monitoring data packet, the driving piece drives the switching frame to slide in the sampling pipeline so as to align the backflushing mechanism with the sampling main pipe, and then the water distribution pump supplies water to the backflushing mechanism and backflushes and cleans the sampling pipeline.

To sum up, the beneficial technical effect of this application does: after the sampling device detects the water quality, the switching frame is driven by the driving piece to horizontally move in the sampling pipeline so as to align the backflushing mechanism with the sampling main pipe, at the moment, the filtering piece enters the accommodating cavity, the water distribution pump is started, and clear water is sprayed into the sampling pipeline through the sampling main pipe and the backflushing mechanism, so that impurities in the sampling pipeline can be effectively flushed, and the cleanliness in the sampling pipeline can be improved; after the washing is accomplished, the driving piece redrives the switching frame so that filter piece and sampling house steward aim at to do benefit to the water sample extraction and the detection of next time, can effectively ensure the accuracy of the monitoring data of this application.

Drawings

Fig. 1 is a sectional view showing the overall structure of a treatment system according to an embodiment of the present application.

Fig. 2 is an enlarged schematic view of a portion a of fig. 1.

Fig. 3 is a schematic flow chart of a processing method according to an embodiment of the present application.

Reference numerals: 1. a sampling pipe; 2. a water distribution pump; 3. water on-line detection equipment; 4. a sampling port; 5. a sampling port; 6. a sampling header pipe; 7. a switching frame; 8. a filter member; 9. an accommodating cavity; 10. a backflushing main pipe; 11. a movable tube; 12. a counter punch; 13. a baffle plate; 14. butt-joint pipes; 15. an elastic member; 16. a transition surface; 17. a partition plate; 18. a seal member; 19. flushing a sewage pipe; 20. a sewage discharge pipe; 21. a blowoff valve; 22. a one-way stop; 23. a sewage collecting pipe; 24. a sewage collecting valve; 25. a three-way pipe; 26. a first solenoid valve; 27. a second solenoid valve.

Detailed Description

The technical solutions of the present application will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are only some embodiments of the present application, but not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

The embodiment of the application discloses a pollution source online detection concurrent data processing system for enterprise technical service. Referring to fig. 1, the online pollution source detection concurrent data processing system for enterprise technical services comprises a storage module, an acquisition module, a processing module and a sending module, wherein a monitoring data packet of the acquisition module is acquired by a sampling device;

the sampling device comprises a sampling pipeline 1, a water distribution pump 2 and water online detection equipment 3, wherein a sampling port 4 and a sampling port 5 are arranged on the sampling pipeline 1, a sampling main pipe 6 is connected to the sampling pipeline 1 at the sampling port 5, and the sampling main pipe 6 is communicated with the water distribution pump 2 and the water online detection equipment 3; specifically, the sampling main pipe 6 is connected with a three-way pipe 25, one end of the three-way pipe 25 is connected with the water distribution pump 2 and is provided with a first electromagnetic valve 26, the other end of the three-way pipe is connected with the water online detection equipment 3 and is provided with a second electromagnetic valve 27, the water distribution pump 2 is communicated with a clean water source, and meanwhile, a pump body for sampling is arranged between the second electromagnetic valve 27 and the water online detection equipment 3.

A switching frame 7 and a driving piece for driving the switching frame 7 to slide along the direction orthogonal to the axial direction of the sampling pipeline 1 are arranged in the sampling pipeline 1, a filtering piece 8 and a backflushing mechanism for butting with the sampling header pipe 6 are sequentially arranged on the switching frame 7, accommodating cavities 9 are formed in two sides of the sampling pipeline 1, and the size of the backflushing mechanism and the size of the filtering piece 8 along the axial direction of the sampling pipeline 1 are not larger than the size of the switching frame 7 and the size of the accommodating cavities 9 along the axial direction of the sampling pipeline 1; when the switching frame 7 slides to align the filter element 8 with the sampling main pipe 6, the recoil mechanism corresponds to one of the accommodating cavities 9; when the switching frame 7 slides to align the recoil mechanism with the sampling manifold 6, the filter element 8 corresponds to the other receiving chamber 9.

After the arrangement, after the sampling device detects the water quality, the switching frame 7 is driven by the driving piece to horizontally move in the sampling pipeline 1 so as to align the backflushing mechanism with the sampling main pipe 6, at the moment, the filtering piece 8 enters the accommodating cavity 9, the second electromagnetic valve 27 is closed, the first electromagnetic valve 26 is opened, the water distribution pump 2 is started, the water distribution pump 2 sprays clear water into the sampling pipeline 1 through the sampling main pipe 6 and the backflushing mechanism, impurities in the sampling pipeline 1 can be effectively washed, and the cleanliness in the sampling pipeline 1 can be improved; after washing the completion, the driving piece redrives and switches frame 7 so that filter 8 and sampling house steward 6 are aimed at, closes first solenoid valve 26 again, opens second solenoid valve 27 to do benefit to the next water sample extraction and the detection of water on-line measuring equipment 3, can effectively ensure the monitoring data's of this application accuracy.

And through the above arrangement, the sampling device can be flexibly switched between the sampling state and the flushing state, has a simple structure and low maintenance cost, and is particularly suitable for remote online monitoring of water quality.

More specifically, referring to fig. 1 and 2, the backflushing mechanism comprises a backflushing main pipe 10 fixedly connected to the switching frame 7, a movable pipe 11 used for being in butt joint with the sampling main pipe 6 is elastically arranged at one end, close to the sampling main pipe 6, of the backflushing main pipe 10, a plurality of backflushing heads 12 obliquely pointing to the inner wall of one end, far away from the sampling main pipe 6, of the sampling pipeline 1 are arranged on the switching frame 7, and the backflushing heads 12 are communicated with the backflushing main pipe 10; in actual arrangement, the backflushing head 12 is connected with the backflushing main pipe 10 through a hose.

In some embodiments, the axial position at which the plurality of counter-punches 12 point towards the sampling manifold 6 is different.

In other embodiments, the counter-punch 12 is hinged to the switching frame 7 and is locked in a bolted manner, so that the flushing angle of the counter-punch 12 is adjustable at a predetermined time, and the counter-punch 12 is connected to the backflushing manifold 10 by a hose.

Referring to fig. 1 and 2, a baffle 13 is fixedly connected in the backflushing main pipe 10, the movable pipe 11 penetrates through the baffle 13 and is in sliding sealing connection with the baffle 13, one end, far away from the backflushing head 12, of the movable pipe 11 is communicated with a butt joint pipe 14 used for being in butt joint with the sampling main pipe 6, the outer diameter of the butt joint pipe 14 is larger than that of the movable pipe 11, an elastic piece 15 is arranged between the butt joint pipe 14 and the baffle 13, the elastic piece 15 is set to be a spring, a transition surface 16 is arranged on the peripheral wall, close to the sampling main pipe 6, of one end of the butt joint pipe 14, and the transition surface 16 is set to be an inclined surface or an arc surface so as to be beneficial to butt joint or separation of the butt joint pipe 14 and the sampling main pipe 6 with the sampling main pipe 6.

Therefore, during sampling, the driving part drives the switching frame 7 to move until the filtering part 8 is aligned with the sampling main pipe 6, at the moment, the butt joint pipe 14 drives the movable pipe 11 to approach the sampling port 4 under the pushing of the inner wall of the sampling pipeline 1, and the elastic part 15 is compressed; and the pump body that communicates with water on-line measuring equipment 3 this moment is with the in-process of sample water suction to water on-line measuring equipment 3 in the sampling pipe 1, filters piece 8 and can carry out effective filtration to the impurity in the sample water to prevent to cause the jam to water on-line measuring equipment 3 to the impurity that does not have the essence meaning to water quality testing.

After sampling is finished, the driving piece drives the switching frame 7 to move to the alignment process of the butt joint pipe 14 and the sampling main pipe 6, the transition surface 16 can play a good transition role in the process that the butt joint pipe 14 is in butt joint with the sampling main pipe 6 and is separated from the butt joint with the sampling main pipe 6, so that the movable pipe 11 can smoothly slide on the baffle 13, and the arrangement of the transition surface 16 can also improve the sealing performance of the butt joint pipe 14 and the sampling main pipe 6 to a certain degree, for example, when the inner diameter of the sampling main pipe 6 is between the inner diameter and the outer diameter of the butt joint pipe 14, after the butt joint pipe 14 is in butt joint with the sampling main pipe 6, the end part of the sampling main pipe 6 is abutted against the transition surface 16, and the sealing performance between the butt joint pipe 14 and the sampling main pipe 6 is stronger. Furthermore, in other embodiments, the inner wall of the end of the sampling header 6 may also be provided with a flared shape to match with the transition surface 16 of the docking pipe 14, so as to further enhance the sealing performance when the two are docked, ensure the amount and pressure of the clear water ejected by the counter punch 12, and ensure the flushing quality of the counter-flushing mechanism.

Therefore, when the butt joint pipe 14 is aligned with the sampling main pipe 6, the deformation force of the elastic piece 15 pushes the butt joint pipe 14 to move upwards so as to enable the butt joint pipe 14 to be abutted against the sampling main pipe 6, and the butt joint pipe 14 and the sampling main pipe 6 can be in sealed connection, so that when the water distribution pump 2 is started, clear water flows through the sampling main pipe 6, the butt joint pipe 14 and the movable pipe 11 to enter the backflushing main pipe 10, and then is sprayed to the inner wall of the sampling pipeline 1 through the plurality of backflushing heads 12, and the sampling pipeline 1 can be effectively cleaned.

And in order to realize the flexible switching of the switching frame 7 between the two accommodating cavities 9 and the inner cavity of the sampling pipeline 1, the driving part is set to be a rack (not shown in the figure) arranged along the length direction of the switching frame 7 and a gear (not shown in the figure) meshed and connected with the rack, the rack is fixedly connected on the side wall of the switching frame 7, the gear rotates and is arranged at the joint part of the accommodating cavities 9 and the inner cavity of the sampling pipeline 1, and the outer of the sampling pipeline 1 is fixedly connected with a waterproof motor of which the output end is coaxially and fixedly connected with the gear.

In order to further reduce the interference of water flow in the inner cavity of the sampling pipeline 1 to the accommodating cavity 9 when the sampling device is in a sampling state and a flushing state, referring to fig. 1, a partition plate 17 is fixedly connected to the middle of the switching frame 7, and sealing parts 18 are arranged on the switching frame 7 and the partition plate 17 along two axial sides of the sampling pipeline 1; when filtering piece 8 or recoil mechanism is located corresponding holding chamber 9, sealing member 18 on division board 17 and holding chamber 9 inner wall butt, and sealing member 18 sets up to the rubber strip.

Thereby when switching frame 7 and driving during filter piece 8 or recoil mechanism get into corresponding holding chamber 9, division board 17 separates this holding chamber 9 and sampling pipe 1 inner chamber, and sealing member 18 seals sampling pipe 1 inner chamber, can effectively reduce the rivers in the sampling pipe 1 to the interference of the holding chamber 9 of accomodating filter piece 8 or recoil mechanism.

Meanwhile, a certain amount of impurities can be collected in the sampling pipeline 1 after the flushing is finished, so, referring to fig. 1, a one-way stopping piece 22 is arranged at the sampling port 4 of the sampling pipeline 1, the one-way stopping piece 22 only allows a medium to enter the sampling pipeline 1 from the outside of the sampling pipeline 1, a sewage collecting pipe 23 is connected to the side wall of the sampling pipeline 1 close to the one-way stopping piece 22, and a sewage collecting valve 24 is arranged on the sewage collecting pipe 23; the one-way stop piece 22 is arranged as a one-way valve, and one end of the sampling pipeline 1 far away from the sampling main pipe 6 is arranged as a closing-in shape, so that impurities can be deposited at the closing-in section as much as possible, and the dirt collecting pipe 23 is arranged at the closing-in section to facilitate the discharge of the impurities.

In the in-service use in-process, also can adsorb certain impurity on filtering piece 8, for further reducing the influence of these impurities to follow-up sample detection work, refer to fig. 1, the holding chamber 9 that is close to filtering piece 8 is connected with one end and the towards dirty pipe 19 that joins in marriage water pump 2 and be connected, and holding chamber 9 still is connected with and washes the blow off pipe 20 that dirty pipe 19 is relative setting, is provided with blowoff valve 21 on the blow off pipe 20. So, when switching over frame 7 and will filtering piece 8 and shift to in the holding chamber 9, can open and join in marriage water pump 2 and wash dirty pipe 19 blowout in order to filtering piece 8 from the clear water, because this rivers direction is reverse in the direction that miscellaneous affairs infiltration filtered piece 8, consequently can effectively clear away the impurity on filtering piece 8, the impurity after being clear away is from blowdown pipe 20 discharges, sampling device's cleanliness factor has further been improved, the precision of the water quality testing data among the continuous on-line monitoring process has effectively been ensured.

The embodiment of the application also discloses a method for processing the online detection concurrent data of the pollution source for the enterprise technical service, and referring to fig. 3, the online detection concurrent data processing system of the pollution source for the enterprise technical service comprises the following steps:

the data storage is realized by storing a preset proportional table, a preset first corresponding relation and a preset second corresponding relation through a storage module, wherein the proportional table comprises node information of a plurality of sub-servers at different time and corresponding utilization rate proportional relations;

acquiring data, namely acquiring a proportion table, and acquiring a monitoring data packet of a current key polluted enterprise through a sampling device;

the data processing module is used for detecting the monitoring data packet, judging whether the monitoring data packet contains environmental quality monitoring data or not, and distributing the electricity utilization data or the electricity data and the environmental quality monitoring data in the monitoring data packet according to the ratio table and the first corresponding relation or the second corresponding relation;

data transmission, namely transmitting the power consumption data and the environmental quality monitoring data distributed and processed by the processing module to corresponding sub-servers through a transmitting module so that the corresponding sub-servers can process part of the received power consumption data or part of the received power consumption data and part of the received environmental quality monitoring data;

wherein after the sampling device acquires the primary monitoring data packet, the switching frame 7 is driven by the driving piece to slide in the sampling pipeline 1 so as to align the backflushing mechanism with the sampling main pipe 6, and then the water is supplied to the backflushing mechanism by the water distribution pump 2 and the sampling pipeline 1 is backflushed and cleaned.

The implementation principle of the pollution source online detection concurrent data processing system for the enterprise technical service in the embodiment of the application is as follows: after the sampling device detects the water quality, the switching frame 7 is driven by the driving piece to horizontally move in the sampling pipeline 1, so that the butt joint pipe 14 is aligned with the sampling main pipe 6, the filtering piece 8 enters the accommodating cavity 9 at the moment, the water distribution pump 2 is started, clear water enters the backflushing main pipe 10 through the sampling main pipe 6, the butt joint pipe 14 and the movable pipe 11, and then is sprayed to the inner wall of the sampling pipeline 1 by the plurality of backflushing heads 12, so that the sampling pipeline 1 can be effectively cleaned, impurities in the sampling pipeline 1 can be effectively washed, and the cleanliness in the sampling pipeline 1 can be improved; after the washing is accomplished, the frame 7 is switched in order to make to filter 8 and the alignment of sampling house steward 6 in the driving piece redriven to do benefit to the water sample extraction and the detection of next time, can effectively ensure the accuracy of the monitoring data of this application.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (10)

1. An online pollution source detection and concurrent data processing system for enterprise technical service comprises: the device comprises a storage module, an acquisition module, a processing module and a sending module, wherein a monitoring data packet of the acquisition module is acquired by a sampling device;

the sampling device comprises a sampling pipeline (1), a water distribution pump (2) and water online detection equipment (3), and is characterized in that the sampling pipeline (1) is provided with a sampling port (4) and a sampling port (5), the sampling pipeline (1) is connected with a sampling main pipe (6) at the sampling port (5), and the sampling main pipe (6) is communicated with the water distribution pump (2) and the water online detection equipment (3);

a switching frame (7) and a driving piece for driving the switching frame (7) to slide along the direction orthogonal to the axial direction of the sampling pipeline (1) are arranged in the sampling pipeline (1), a filtering piece (8) and a recoil mechanism for butting with the sampling main pipe (6) are sequentially arranged on the switching frame (7), and accommodating cavities (9) are arranged on two sides of the sampling pipeline (1);

when the switching frame (7) slides to the state that the filter pieces (8) are aligned with the sampling main pipe (6), the recoil mechanism corresponds to one of the accommodating cavities (9);

when the switching frame (7) slides to the state that the recoil mechanism is aligned with the sampling main pipe (6), the filter piece (8) corresponds to the other accommodating cavity (9).

2. The pollution source online detection and concurrency data processing system for the enterprise technical services as claimed in claim 1, wherein the backflushing mechanism comprises a backflushing main pipe (10) fixedly connected to the switching frame (7), a movable pipe (11) used for being in butt joint with the sampling main pipe (6) is elastically arranged at one end, close to the sampling main pipe (6), of the backflushing main pipe (10), a plurality of anti-punching heads (12) obliquely pointing to the inner wall of the sampling pipeline (1) are arranged on the switching frame (7), and the anti-punching heads (12) are communicated with the backflushing main pipe (10).

3. The online pollution source detection and concurrency data processing system for enterprise technical services, according to claim 2, is characterized in that a baffle (13) is fixedly connected in the backflushing main pipe (10), the movable pipe (11) penetrates through the baffle (13) and is connected with the baffle (13) in a sliding and sealing manner, a butt joint pipe (14) for butt joint with the sampling main pipe (6) is communicated with one end, away from the backflushing head (12), of the movable pipe (11), the outer diameter of the butt joint pipe (14) is larger than that of the movable pipe (11), and an elastic piece (15) is arranged between the butt joint pipe (14) and the baffle (13).

4. The system for on-line detection and concurrent data processing of pollution sources for enterprise technical services as claimed in claim 3, wherein the peripheral wall of one end of the butt joint pipe (14) close to the sampling header pipe (6) is provided with a transition surface (16).

5. The online pollution source detection and concurrency data processing system for the enterprise technical service according to any one of claims 1 to 4, wherein a partition plate (17) is fixedly connected to the middle of the switching frame (7), and sealing members (18) are arranged on both sides of the switching frame (7) and the partition plate (17) along the axial direction of the sampling pipeline (1);

when the filter element (8) or the recoil mechanism is positioned in the corresponding accommodating cavity (9), the sealing element (18) on the partition plate (17) is abutted against the inner wall of the accommodating cavity (9).

6. The online detection and concurrency data processing system for the pollution sources for the enterprise technical services as claimed in any one of claims 1 to 4, wherein the accommodating cavity (9) close to the filter member (8) is connected with a sewage flushing pipe (19) with one end connected with the water distribution pump (2), the accommodating cavity (9) is further connected with a sewage draining pipe (20) which is arranged opposite to the sewage flushing pipe (19), and a sewage draining valve (21) is arranged on the sewage draining pipe (20).

7. The system for on-line detection and data processing of pollution sources for enterprise technical services according to any one of claims 1 to 4, characterized in that the sampling pipe (1) is provided with a one-way stop (22) at the sampling port (4), and the one-way stop (22) allows only medium to enter the sampling pipe (1) from outside the sampling pipe (1).

8. The system for online detection and concurrent data processing of the pollution source for the enterprise technical service according to claim 7, wherein a sewage collecting pipe (23) is connected to a side wall of the sampling pipeline (1) close to the one-way stopping member (22), and a sewage collecting valve (24) is arranged on the sewage collecting pipe (23).

9. The system for on-line detection and data processing of pollution sources for enterprise technical services according to any one of claims 1 to 4, characterized in that a tee pipe (25) is connected to the sampling header pipe (6), one end of the tee pipe (25) is connected to the water distribution pump (2) and is provided with a first electromagnetic valve (26), and the other end of the tee pipe is connected to the water on-line detection equipment (3) and is provided with a second electromagnetic valve (27).

10. An online pollution source detection and concurrent data processing method for enterprise technical services, which uses the online pollution source detection and concurrent data processing system for enterprise technical services as claimed in any one of claims 1-9, and comprises the following steps:

storing data, namely storing a preset ratio table, a preset first corresponding relation and a preset second corresponding relation through the storage module, wherein the ratio table comprises node information of a plurality of sub-servers at different time and corresponding utilization ratio proportional relations;

acquiring data, namely acquiring the proportional table, and acquiring a monitoring data packet of the current key polluted enterprise through the sampling device;

data processing, namely detecting the monitoring data packet through the processing module, judging whether the monitoring data packet contains environmental quality monitoring data or not, and distributing the electricity utilization data or the electricity data and the environmental quality monitoring data in the monitoring data packet according to the ratio table and the first corresponding relation or the second corresponding relation;

data transmission, namely transmitting the power consumption data and the environmental quality monitoring data distributed and processed by the processing module to corresponding sub-servers through a transmitting module so that the corresponding sub-servers can process part of the received power consumption data or part of the received power consumption data and part of the received environmental quality monitoring data;

after the sampling device acquires a primary monitoring data packet, the driving piece drives the switching frame (7) to slide in the sampling pipeline (1) so that the backflushing mechanism is aligned with the sampling main pipe (6), and then the water distribution pump (2) supplies water to the backflushing mechanism and performs backflushing cleaning on the sampling pipeline (1).

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