CN114477419A

CN114477419A - Circulating ozone comprehensive utilization control system

Info

Publication number: CN114477419A
Application number: CN202210144397.6A
Authority: CN
Inventors: 王建平; 胡磊; 张鹏
Original assignee: Henan Aorui Environmental Protection Technology Co ltd
Current assignee: Henan Aorui Environmental Protection Technology Co ltd
Priority date: 2022-02-17
Filing date: 2022-02-17
Publication date: 2022-05-13
Anticipated expiration: 2042-02-17
Also published as: CN114477419B

Abstract

The invention relates to the technical field of ozone recycling, and discloses a circulating type comprehensive ozone utilization control system which comprises an ozone shunt module, wherein the connecting end of the ozone shunt module is connected with a plurality of source shunt sub-modules, the connecting ends of the source shunt sub-modules are connected with source shunt control sub-modules, and the input ends of the source shunt sub-modules are connected with shunt monitoring modules; according to the invention, by arranging the shunting regulation and control module and the recycling and distribution module, the shunting monitoring module monitors the ozone flow in the shunting pipeline in real time, the residual monitoring module monitors the ozone amount entering each disinfection device and the residual ozone amount after reaction in real time, the shunting regulation and control module regulates and closes the flow velocity of the shunting pipeline, the recycling and distribution module extracts the redundant ozone in the disinfection device, and then distributes the extracted ozone to each device which is not completely disinfected, so that waste can be effectively avoided, and the reasonable utilization rate and the use amount management effect of the ozone are improved.

Description

Circulating ozone comprehensive utilization control system

Technical Field

The invention relates to the technical field of ozone recycling, in particular to a circulating type comprehensive ozone utilization control system.

Background

Ozone has strong oxidizing property, is an oxidant stronger than oxygen, can be used as a strong oxidant, and can be used for the disinfection and deodorization of bleaching agents, fur deodorizers, air purifiers, disinfectants and drinking water, and the product after the ozone reaction is oxygen, so the ozone is an efficient oxidant without secondary pollution.

In the prior art, after an ozone generator generates ozone, the ozone is led to each disinfection treatment device for disinfection, but because the ozone is used in a plurality of ways, the amount of the ozone in each device in the same direction is difficult to control, and the redundant ozone is difficult to reasonably utilize.

Disclosure of Invention

Technical problem to be solved

Aiming at the defects of the prior art, the invention provides a circulating type comprehensive ozone utilization control system, which solves the problems that the ozone quantity in each device in the same direction is difficult to control and the redundant ozone is difficult to reasonably utilize due to more using ways.

(II) technical scheme

In order to achieve the purpose, the invention provides the following technical scheme: a circulating ozone comprehensive utilization control system comprises an ozone shunt module, wherein a connecting end of the ozone shunt module is connected with a plurality of source shunt sub-modules, connecting ends of the source shunt sub-modules are connected with source sub-control sub-modules, input ends of the source sub-modules are connected with shunt monitoring modules, output ends of the source sub-modules are connected with shunt regulation and control modules, the source sub-modules are connected with a master control module in a signal mode, the master control module is connected with a plurality of application sub-modules in a signal mode, input ends of the application sub-modules are connected with a surplus monitoring module in a signal mode, output ends of the application sub-modules are connected with a recovery distribution module, the ozone shunt module comprises a shunt control unit and a shunt selection unit, and the shunt regulation and control module comprises a flow speed adjusting unit and a shunt opening and closing unit, the recovery distribution module comprises a residual extraction unit and a flow direction selection distribution unit;

the ozone shunt module is used for selecting the number of shunts according to the number of the disinfection equipment and sending instructions to the source shunt submodules for on-off control;

the source shunting submodule is used for receiving an instruction of the ozone shunting module and controlling the shunt pipeline to be opened and closed;

the source sub-control module is used for receiving the real-time monitoring data of the shunt monitoring module, analyzing and processing the data, sending the received data to the master control module, and sending an instruction to the shunt regulation and control module;

the shunt monitoring module is used for monitoring the ozone flow in the shunt pipeline and the pressure in the shunt pipeline in real time and transmitting the monitored data to the source sub-control sub-module;

the shunt regulation and control module is used for receiving a command of the source shunt control submodule, regulating the flow rate of the shunt pipeline and playing a role in standby opening and closing when the source shunt submodule fails in function;

the purpose sub-control sub-module is used for receiving real-time monitoring data of the allowance monitoring module, then sending the data to the main control module, and sending an instruction to the recycling and distributing module according to the monitoring data;

the residual monitoring module is used for monitoring the amount of ozone entering each disinfection device and the amount of residual ozone after reaction in real time, detecting the disinfection degree in the disinfection devices and sending the detected data to the application sub-control sub-module;

the recovery and distribution module is used for receiving the instruction of the use sub-control sub-module, extracting redundant ozone in the disinfection equipment and then distributing the extracted ozone to each incompletely disinfected equipment.

Preferably, the ozone shunt module is specifically configured to select the number of shunt pipelines to which ozone flows according to the number of disinfection devices through the shunt selection unit, and send instructions to the multiple source shunt sub-modules through the shunt control unit to perform on-off control.

Preferably, the source sub-control sub-modules, the shunt monitoring modules and the shunt regulation and control modules form real-time monitoring sub-stations of the shunt pipelines, and the surplus monitoring modules and the use sub-control sub-modules form real-time monitoring sub-stations of the use terminals.

Preferably, the shunt regulation and control module is specifically used for receiving a command of the source shunt control submodule, adjusting the flow rate of ozone in the shunt pipeline through the flow rate adjusting unit, and playing a role in standby opening and closing when the source shunt submodule fails in function through the shunt opening and closing unit.

Preferably, the recycling and distributing module is specifically configured to receive an instruction of the usage sub-control module, extract redundant ozone in each disinfection device through the remaining extracting unit, and then distribute the extracted ozone to each incompletely disinfected device through the flow direction selecting and distributing unit.

Preferably, the ozone generator further comprises a real-time monitoring module, wherein the real-time monitoring module is connected with the input end of the master control module and is used for monitoring the pressure, the total generation amount and the temperature of the ozone generator in real time.

Preferably, the real-time monitoring module includes pressure monitoring unit, generation total amount monitoring unit and temperature monitoring unit, the real-time monitoring module specifically is used for monitoring ozone generator's tank internal pressure through pressure monitoring unit, monitors the ozone total amount that ozone generator generated through generating total amount monitoring unit, monitors ozone generator's temperature through temperature monitoring unit.

Preferably, the output end of the master control module is connected with a loss statistical module, and the output end of the loss statistical module is connected with a loss point analysis module.

Preferably, the loss statistics module is used for counting the total amount of ozone entering each shunt pipeline and the total amount of ozone entering each device, and comparing the total amounts at two ends.

Preferably, the depletion point analysis module is used for comparing the ozone amount of each shunt pipeline with the ozone amount entering each device, and analyzing the shunt pipeline generating ozone depletion.

(III) advantageous effects

The invention provides a circulating type comprehensive ozone utilization control system, which has the following beneficial effects:

(1) the ozone disinfection system is provided with the shunt regulation and control module and the recovery and distribution module, the ozone shunt module selects the shunt according to the number of the disinfection devices, the shunt monitoring module monitors the ozone flow in the shunt pipeline in real time, the residual monitoring module monitors the ozone amount entering each disinfection device and the residual ozone amount after reaction in real time and detects the disinfection degree in the disinfection devices, the master control module obtains the ozone demand and the residual ozone amount in each device and each shunt pipeline, then the shunt regulation and control module regulates and closes the flow rate of the shunt pipeline, the recovery and distribution module extracts the residual ozone in the disinfection devices, and then the extracted ozone is distributed to each device which is not completely disinfected, so that waste can be effectively avoided.

(2) The invention can carry out real-time data monitoring on the ozone generator by arranging the real-time monitoring module, thereby improving the safety and the working stability of the ozone generator.

(3) By arranging the loss statistical module and the loss point analysis module, the ozone partial loss and the total ozone loss of each shunt pipeline can be counted, so that the ozone can be supplemented conveniently and timely, and the sufficient ozone can be introduced.

Drawings

FIG. 1 is a block diagram of a system of the present invention;

FIG. 2 is a block diagram of an ozone shunt module of the present invention;

FIG. 3 is a block diagram of a shunt regulation module according to the present invention;

FIG. 4 is a block diagram of a recycling allocation module according to the present invention;

FIG. 5 is a block diagram of a real-time monitoring module according to the present invention.

In the figure: 1. an ozone shunt module; 2. a source splitting submodule; 3. a source sub-control module; 4. a shunt monitoring module; 5. a shunt regulation module; 6. a master control module; 7. a usage sub-control module; 8. a margin monitoring module; 9. a recycling distribution module; 10. an ozone generator; 11. a real-time monitoring module; 12. a shunt control unit; 13. a shunt selection unit; 14. a flow rate adjusting unit; 15. a shunt opening and closing unit; 16. a residual extraction unit; 17. a flow direction selection allocation unit; 18. a pressure monitoring unit; 19. generating a total amount monitoring unit; 20. and a temperature monitoring unit.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the 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 invention.

As shown in fig. 1 to 5, the present invention provides a technical solution: a circulating ozone comprehensive utilization control system comprises an ozone shunt module 1, wherein a connecting end of the ozone shunt module 1 is connected with a plurality of source shunt sub-modules 2, the connecting end can conveniently select and control the number and the opening and closing conditions of shunt pipelines, the source shunt sub-modules 2 can adopt electromagnetic valves to carry out opening and closing control on the shunt pipelines, the connecting ends of the source shunt sub-modules 2 are connected with source shunt sub-modules 3, the input ends of the source shunt sub-modules 3 are connected with shunt monitoring modules 4, the shunt monitoring modules 4 can monitor the ozone amount in each shunt pipeline in real time and conveniently carry out shunt control treatment, the output ends of the source shunt sub-modules 3 are connected with shunt regulation and control modules 5, the flow rate of ozone in each shunt pipeline can be conveniently controlled, and a standby function of opening and closing pipelines can be achieved, the ozone disinfection system has the advantages that a good insurance effect is achieved, the source sub-control sub-modules 3 are in signal connection with the master control module 6, the overall control and data analysis can be conveniently carried out by a user, the master control module 6 is in signal connection with the purpose sub-control sub-modules 7, the input ends of the purpose sub-modules 7 are all connected with the residual monitoring module 8, the ozone entering each disinfection device can be monitored in real time, the output ends of the purpose sub-modules 7 are connected with the recovery distribution module 9, the residual ozone can be recovered and recycled, the utilization rate of the ozone is improved, the ozone shunt module 1 comprises a shunt control unit 12 and a shunt selection unit 13, the shunt regulation and control module 5 comprises a flow rate regulation unit 14 and a shunt opening and closing unit 15, the recovery distribution module 9 comprises a residual extraction unit 16 and a flow direction selection and distribution unit 17, the utilization rate of ozone can be effectively improved, and the waste of resources is avoided;

the ozone shunt module 1 is used for selecting the number of shunts according to the number of the disinfection equipment, sending instructions to the source shunt sub-modules 2 for on-off control, and conveniently controlling each shunt pipeline;

the source shunting submodule 2 is used for receiving an instruction of the ozone shunting module 1 and controlling the on-off of the shunting pipeline so as to effectively control the flow direction of ozone;

the source sub-control module 3 is used for receiving the real-time monitoring data of the shunt monitoring module 4, analyzing and processing the data, sending the received data to the master control module 6, and issuing instructions to the shunt regulation and control module 5, so that the control effect on each shunt pipeline can be improved;

the shunt monitoring module 4 is used for monitoring the ozone flow in the shunt pipeline and the pressure in the shunt pipeline in real time, transmitting the monitored data to the source sub-control sub-module 3, and conveniently monitoring each shunt pipeline in real time;

the shunt regulation and control module 5 is used for receiving a command of the source shunt control submodule 3, regulating the flow rate of the shunt pipeline and changing the amount of ozone and the flow rate of ozone introduced into each disinfection device, so that the amount of ozone in each disinfection device can be in a proper amount, the comprehensive utilization effect of ozone is improved, a standby opening and closing function can be realized when the source shunt submodule 2 fails, and a good safety function is realized;

the purpose sub-control module 7 is used for receiving the real-time monitoring data of the residual monitoring module 8, then sending the data to the main control module 6, and sending an instruction to the recovery distribution module 9 according to the monitoring data, so that the flow direction control effect of ozone can be improved;

the residual monitoring module 8 is used for monitoring the ozone amount entering each disinfection device and the residual ozone amount after reaction in real time, detecting the disinfection degree in the disinfection device and sending the detected data to the application sub-control sub-module 7, so that the ozone consumption condition of each disinfection device can be known, and regulation, control, recovery and distribution are convenient;

the recycling and distributing module 9 is used for receiving the instruction of the use sub-control sub-module 7, extracting redundant ozone in the disinfection equipment, and distributing the extracted ozone to each incompletely disinfected equipment, so that waste can be effectively avoided.

Further, the ozone shunt module 1 is specifically configured to select the number of shunt pipelines in the flow direction of ozone according to the number of disinfection devices through the shunt selection unit 13, and send instructions to the multiple source shunt submodules 2 through the shunt control unit 12 to perform on-off control, so that the number and the on-off conditions of the shunt pipelines can be conveniently selected and controlled.

Furthermore, the source sub-control sub-module 3, the shunt monitoring module 4 and the shunt regulation and control module 5 form a plurality of shunt pipeline real-time monitoring sub-stations, the surplus monitoring module 8 and the usage sub-control sub-module 7 form a plurality of usage terminal real-time monitoring sub-stations, the management granularity of each shunt pipeline can be refined, and control, monitoring and management are convenient.

Furthermore, the shunting regulation and control module 5 is specifically used for receiving the command of the source sub-control module 3, regulating the flow rate of ozone in the shunting pipeline through the flow rate regulating unit 14, and playing a role in standby opening and closing when the source shunting sub-module 2 fails in function through the shunting opening and closing unit 15, so that the management granularity of ozone entering each disinfection device can be refined.

Further, the recycling and distributing module 9 is specifically configured to receive an instruction of the usage sub-control module 7, extract redundant ozone in each disinfection device through the residual extracting unit 16, and distribute the extracted ozone to each device that is not completely disinfected through the flow direction selecting and distributing unit 17, so that the utilization rate of ozone can be effectively improved, and waste of resources is avoided.

Further, the ozone generator safety monitoring system further comprises a real-time monitoring module 11, wherein the real-time monitoring module 11 is connected with the input end of the master control module 6, and the real-time monitoring module 11 is used for monitoring the pressure, the total generation amount and the temperature of the ozone generator 10 in real time, so that the safety of the ozone generator 10 can be ensured.

Further, the real-time monitoring module 11 includes a pressure monitoring unit 18, a generation total amount monitoring unit 19 and a temperature monitoring unit 20, the real-time monitoring module 11 is specifically configured to monitor the tank internal pressure of the ozone generator 10 through the pressure monitoring unit 18, monitor the total amount of ozone generated by the ozone generator 10 through the generation total amount monitoring unit 19, monitor the temperature of the ozone generator 10 through the temperature monitoring unit 20, and can monitor the ozone generator 10 in real time, thereby improving the safety.

Furthermore, the output end of the master control module 6 is connected with a loss statistical module, the output end of the loss statistical module is connected with a loss point analysis module, and the loss generated by conveying ozone can be counted, so that the ozone can be supplemented in time.

Further, loss statistics module is arranged in the total amount of ozone that gets into in each reposition of redundant personnel pipeline and the total amount of ozone that gets into in each equipment of statistics to the total amount at both ends is compared, thereby can obtain the total loss volume of ozone, and convenient in time supplyes ozone.

Furthermore, the depletion point analysis module is used for comparing the ozone amount of each shunt pipeline and the ozone amount entering each device, analyzing the shunt pipelines generating ozone depletion, and performing statistical analysis on the depletion amount of each shunt pipeline respectively, so that corresponding ozone can be supplemented to different pipelines conveniently.

In conclusion, the working process of the invention is as follows: in practical use, the ozone generator 10 works to generate ozone, the ozone shunt module 1 selects the shunt number according to the number of the disinfection equipment, and sends instructions to the source shunt submodules 2 to control the on-off of each shunt pipeline, the ozone is introduced into each shunt pipeline, the shunt monitoring module 4 monitors the ozone flow and the pressure in the shunt pipeline in real time, and transmits the monitored data to the source shunt submodule 3, the residual monitoring module 8 monitors the ozone amount entering each disinfection equipment and the residual ozone amount after reaction in real time, and detects the disinfection degree in the disinfection equipment, and transmits the detected data to the purpose shunt submodule 7, the purpose shunt submodule 7 and the source shunt submodule 3 transmit the data to the master control module 6 for analysis, so as to obtain the ozone demand and the residual ozone amount in each equipment and each shunt pipeline, then according to the shunting regulation and control module 5 receives the command of the source sub-control sub-module 3, the shunting pipeline is regulated and closed in flow rate, the recovery and distribution module 9 receives the command of the use sub-control sub-module 7, redundant ozone in the disinfection equipment is extracted, and the extracted ozone is distributed to each incompletely disinfected equipment, so that waste can be effectively avoided.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. A circulating ozone comprehensive utilization control system is characterized in that: including ozone module (1) along separate routes, the link of ozone module (1) along separate routes submodule piece (2) in a plurality of sources is connected with, and is a plurality of the link of source reposition of redundant personnel submodule piece (2) all is connected with source branch control submodule piece (3), and is a plurality of the input of source branch control submodule piece (3) all is connected with reposition of redundant personnel monitoring module (4), and is a plurality of the output of source branch control submodule piece (3) all is connected with reposition of redundant personnel regulation and control module (5), and is a plurality of source branch control submodule piece (3) signal connection has total control module (6), total control module (6) signal connection has a plurality of uses branch control submodule piece (7), and is a plurality of the input of uses branch control submodule piece (7) all is connected with surplus monitoring module (8), and is a plurality of uses branch control submodule piece (7) output is connected with retrieves distribution module (9), ozone module (1) along separate routes is including along separate routes control unit (12) and select unit (13) The flow-dividing regulation and control module (5) comprises a flow-speed regulation unit (14) and a flow-dividing opening and closing unit (15), and the recovery and distribution module (9) comprises a residual extraction unit (16) and a flow-direction selection and distribution unit (17);

the ozone shunt module (1) is used for selecting the number of shunts according to the number of disinfection equipment and sending instructions to the source shunt submodules (2) for on-off control;

the source shunting submodule (2) is used for receiving an instruction of the ozone shunting module (1) and controlling the on-off of the shunting pipeline;

the source sub-control module (3) is used for receiving the real-time monitoring data of the shunt monitoring module (4), analyzing and processing the data, sending the received data to the master control module (6) and sending an instruction to the shunt regulation and control module (5);

the shunt monitoring module (4) is used for monitoring the ozone flow in the shunt pipeline and the pressure in the pipeline in real time and transmitting the monitored data to the source sub-control sub-module (3);

the shunt regulation and control module (5) is used for receiving a command of the source shunt control submodule (3), regulating the flow rate of a shunt pipeline and playing a role in standby opening and closing when the source shunt submodule (2) fails in function;

the purpose sub-control sub-module (7) is used for receiving real-time monitoring data of the allowance monitoring module (8), then sending the data to the main control module (6), and sending an instruction to the recycling and distributing module (9) according to the monitoring data;

the residual quantity monitoring module (8) is used for monitoring the ozone quantity entering each disinfection device and the residual ozone quantity after reaction in real time, detecting the disinfection degree in the disinfection device and sending the detected data to the application sub-control sub-module (7);

the recovery and distribution module (9) is used for receiving the instruction of the use sub-control sub-module (7), extracting redundant ozone in the disinfection equipment and then distributing the extracted ozone to each incompletely disinfected equipment.

2. The circulating ozone comprehensive utilization control system according to claim 1, characterized in that: the ozone shunt module (1) is specifically used for selecting the number of shunt pipelines in which ozone flows according to the number of disinfection equipment through a shunt selection unit (13), and sending instructions to the source shunt sub-modules (2) through a shunt control unit (12) to perform on-off control.

3. The circulating ozone comprehensive utilization control system according to claim 1, characterized in that: the source sub-control sub-modules (3), the shunt monitoring modules (4) and the shunt regulation and control modules (5) form real-time monitoring sub-stations of a plurality of shunt pipelines, and the surplus monitoring modules (8) and the application sub-control sub-modules (7) form real-time monitoring sub-stations of a plurality of application terminals.

4. The circulating ozone comprehensive utilization control system according to claim 1, characterized in that: the shunt regulation and control module (5) is specifically used for receiving a command of the source shunt control submodule (3), regulating the flow rate of ozone in a shunt pipeline through the flow rate regulating unit (14), and playing a role in standby opening and closing when the source shunt submodule (2) fails in function through the shunt opening and closing unit (15).

5. The circulating ozone comprehensive utilization control system according to claim 1, characterized in that: the recovery and distribution module (9) is specifically used for receiving the instruction of the use sub-control module (7), extracting redundant ozone in each disinfection device through the residual extraction unit (16), and then distributing the extracted ozone to each incompletely disinfected device through the flow direction selection and distribution unit (17).

6. The circulating ozone comprehensive utilization control system according to claim 1, characterized in that: the ozone generator is characterized by further comprising a real-time monitoring module (11), wherein the real-time monitoring module (11) is connected with the input end of the master control module (6), and the real-time monitoring module (11) is used for monitoring the pressure, the total generation amount and the temperature of the ozone generator (10) in real time.

7. The circulating ozone comprehensive utilization control system according to claim 6, characterized in that: real-time supervision module (11) are including pressure monitoring unit (18), generate total amount monitoring unit (19) and temperature monitoring unit (20), real-time supervision module (11) specifically are used for monitoring the tank internal pressure of ozone generator (10) through pressure monitoring unit (18), monitor the ozone total amount that ozone generator (10) generated through generating total amount monitoring unit (19), monitor the temperature of ozone generator (10) through temperature monitoring unit (20).

8. The circulating ozone comprehensive utilization control system according to claim 1, characterized in that: the output end of the master control module (6) is connected with a loss statistical module, and the output end of the loss statistical module is connected with a loss point analysis module.

9. The circulating ozone comprehensive utilization control system according to claim 8, characterized in that: the loss statistics module is used for counting the total amount of ozone entering each shunt pipeline and the total amount of ozone entering each device, and comparing the total amounts at two ends.

10. The circulating ozone comprehensive utilization control system according to claim 9, characterized in that: the loss point analysis module is used for comparing the ozone amount of each shunt pipeline with the ozone amount entering each device and analyzing the shunt pipeline generating ozone loss.