CN112943522B - Intelligent queuing alternate working method for multiple working pumps and multiple standby pumps - Google Patents

Abstract

A hydraulic governor hydraulic system operating state control method of the hydraulic turbine, it is an oil pump under the hydraulic governor hydraulic control system operating state working condition of the hydraulic turbine opens and stops and adds the electrical control method of the unloading control, aim at solving and how to control opening and closing and adding and unloading of the hydraulic control system oil pump of the hydraulic turbine governor according to the systematic pressure gathered, the problem of maintaining the hydraulic governor hydraulic control system pressure of the hydraulic turbine to stabilize near rated pressure for a long time; the long-term safe and stable operation of an oil pump of the speed regulator hydraulic control system is ensured, and the speed regulator hydraulic control system can provide a pressure oil source with long-term stability and standard indexes of pressure and the like to operate the guide vane opening actuating mechanism.

Description

Intelligent queuing alternate working method for multiple working pumps and multiple standby pumps

Technical Field

The invention relates to the technical field of hydraulic control of a speed regulator of a hydroelectric generating set, in particular to a method for controlling the running state of a hydraulic system of the speed regulator of a hydraulic turbine.

Background

The speed regulator of the hydroelectric generating set adjusts the opening degree of the guide vane, the power and the frequency of the generating set, and a hydraulic control system of the speed regulator is required to provide a long-acting stable pressure oil source with indexes reaching standards in all aspects such as pressure, temperature, pressure oil particle content and the like to operate the opening degree actuating mechanism of the guide vane. At present, a systematic and detailed control method for pressure maintaining equipment such as an oil pump motor and the like is not disclosed in an operating state of a speed regulator electric control system of the hydroelectric generating set. Because the oil has the characteristic of difficult compressibility, in order to ensure that the oil has relatively stable pressure, part of gas must be filled in the pressure container, and the hydraulic control system of the speed regulator is required to start, stop, add and unload the pressure maintenance equipment such as the oil pump motor and the like according to the oil pressure in the pressure container in the operating state.

In the prior art, the research of a speed regulator hydraulic control system is focused on the research of the structural design and the control performance of guide vane operation actuating mechanisms such as electro-hydraulic conversion, hydraulic amplification and the like, and the disclosed, systematic and comprehensive research data is less in the aspects of the control structural design of the speed regulator hydraulic control system in the aspects of hydraulic pressure, liquid level, oil temperature, oil-mixed water, oil particulate matter content and the like, the control methods of pressure maintaining equipment, oil filtering equipment, temperature control equipment, air supplementing equipment and the like. Chinese patent "oil pressure device for hydro governor and its hydro governor" (application number: 201921922421.4) only discloses an oil pressure device for hydro governor and its electrical control system circuit structure of hydro governor, and does not relate to software control logic processing method.

Disclosure of Invention

The invention provides a method for controlling the running state of a hydraulic system of a hydraulic turbine governor, which is an electrical control method for controlling the starting and stopping, loading and unloading of an oil pump under the working condition of the running state of the hydraulic control system of the hydraulic turbine governor. The method aims to solve the problem of controlling the start-stop, loading and unloading of an oil pump of a hydraulic control system of the hydraulic turbine governor according to the collected system pressure and maintaining the pressure of the hydraulic control system of the hydraulic turbine governor to be stable near the rated pressure for a long time. The invention can ensure the long-term safe and stable operation of the oil pump of the hydraulic control system of the speed regulator; the pressure oil source with long-term stability and standard indexes of pressure and the like can be provided to operate the guide vane opening actuating mechanism.

The technical scheme adopted by the invention is as follows:

a method for controlling the running state of a hydraulic system of a hydraulic turbine governor comprises the following steps:

step 1, a controller detects whether a hydraulic control system is in an operating state, and if so, the step 2 is entered; if not, continuing the detection in the step;

step 2, the controller detects whether the system pressure is less than P1, if yes, the step 3 is carried out; if not, returning to the step 1;

detecting whether the system pressure is less than P2, if yes, entering step 11; if not, returning to the step 1;

detecting whether the system pressure is less than P3, if yes, entering step 19; if not, returning to the step 1;

detecting whether the system pressure is greater than P1', if yes, entering step 27; if not, returning to the step 1;

detecting whether the system pressure is greater than P2', if yes, entering step 30; if not, returning to the step 1;

detecting whether the system pressure is greater than P3', if yes, entering step 33; if not, returning to the step 1.

Step 3, the controller detects whether the system pressure is less than P1, the holding time is T1, and the main pump with the first priority is not loaded, if yes, the step 4 is carried out; if not, returning to the step 1.

And 4, the controller sends a main pump starting command with a first priority, and the step 5 is entered.

Step 5, the controller detects whether the delay time t1 of the main pump starting command with the first priority is reached, if yes, the step 6 is carried out; if not, continuing the detection in the step.

Step 6, the controller detects whether the main pump with the first priority is in a starting state, and if yes, the step 7 is carried out; if not, entering the step 10;

and 7, the controller sends a loading command of the main pump with the first priority, and the step 8 is entered.

Step 8, the controller detects whether the delay time t2 of the loading command of the main pump with the first priority is reached, if yes, the step 9 is executed; if not, continuing the detection in the step.

Step 9, the controller detects whether the main pump with the first priority is in a loading state, and if so, the step 1 is carried out; if not, sending a main pump stop command with a first priority, and entering step 10;

step 10, refreshing the priority of the pump by adopting an intelligent queuing alternate working method of a plurality of working pumps and a plurality of standby pumps, and entering step 4.

Step 11, the controller detects whether the system pressure is less than P2, the holding time is T2, and the main pump with the second priority is not loaded, if yes, the step 12 is executed; if not, returning to the step 1.

And step 12, the controller sends a main pump starting command with the second priority level, and the step 13 is entered.

Step 13, the controller detects whether the delay time t3 of the main pump starting command with the second priority is reached, if yes, the step 14 is executed; if not, continuing the detection in the step.

Step 14, the controller detects whether the main pump with the second priority is in a starting state, and if yes, the step 15 is carried out; if not, go to step 18.

Step 15, the controller issues a load command of the main pump with the second priority, and the process goes to step 16.

Step 16, the controller detects whether the delay time t4 of the loading command of the main pump with the second priority is reached, if yes, the step 17 is executed; if not, continuing the detection in the step.

Step 17, the controller detects whether the main pump with the second priority is in a loading state, and if so, the step 1 is carried out; if not, a main pump stop command with the second priority is issued, and the process proceeds to step 18.

Step 18, adopting an intelligent queuing alternate working method of a plurality of working pumps and a plurality of standby pumps to refresh the priority of the pumps, and entering step 12.

Step 19, the controller detects whether the system pressure is less than P3, the holding time is T3, and the main pump with the third priority is not loaded, if yes, the step 20 is executed; if not, returning to the step 1.

In step 20, the controller issues a main pump start command with a third priority, and the process proceeds to step 21.

Step 21, the controller detects whether the delay time t5 of the main pump starting command of the third priority is up, if yes, the step 22 is executed; if not, continuing the detection in the step.

Step 22, the controller detects whether the main pump with the third priority is in a starting state, if yes, the step 23 is carried out; if not, go to step 26;

step 23, the controller issues a load command of the main pump with the third priority, and the process goes to step 24.

Step 24, the controller detects whether a delay time t6 of a loading command of the main pump sending the third priority is reached, if yes, the step 25 is executed; if not, continuing the detection in the step.

Step 25, the controller detects whether the main pump with the third priority is in a loading state, and if so, the step 1 is executed; if not, a main pump stop command with the third priority is issued, and the process goes to step 26.

And step 26, refreshing the priority of the pump by adopting an intelligent queuing alternate working method of a plurality of working pumps and a plurality of standby pumps, and entering the step 20.

Step 27, the controller detects whether the system pressure is greater than P1', the holding time is T4, and the main pump with the first priority operates or is loaded, if yes, the step 28 is executed; if not, returning to the step 1.

In step 28, the controller issues a main pump unload command with a first priority, and the process proceeds to step 29.

And step 29, the controller sends a main pump stop command with a first priority, and the step 1 is entered.

Step 30, the controller detects whether the system pressure is greater than P2', the holding time is T5, and the main pump with the second priority operates or is loaded, if yes, the step 31 is executed; if not, returning to the step 1.

In step 31, the controller issues a main pump unload command with the second priority, and the process proceeds to step 32.

And step 32, the controller sends a main pump stop command with the second priority to enter step 1.

Step 33, the controller detects whether the system pressure is greater than P3', the holding time is T6, and the main pump with the third priority operates or is loaded, if yes, the step 34 is executed; if not, returning to the step 1.

In step 34, the controller issues a main pump unload command with priority level three, and the process proceeds to step 35.

And step 35, the controller sends a main pump stop command with a third priority, and the step 1 is entered.

An intelligent queuing alternate working method for a plurality of working pumps and a plurality of standby pumps comprises the following steps:

s1: and initializing, and determining the number i of the working pumps of the system and the total number j of the pumps.

S2: and collecting multiple working condition factors of all pumps and determining various working condition values of all pumps.

S3: and (4) carrying out weight sequencing according to various working condition factors of all the pumps, and determining the weight values of various working condition factors of all the pumps.

S4: and calculating the priority score of each pump according to the working condition values corresponding to the various working condition factors of all the pumps and the weight values corresponding to the corresponding working condition factors.

S5: prioritizing all pumps in the system according to the priority score of each pump;

S6: according to the priority sequence of all pumps, the front i pumps with the priority sequence from high to low are taken as working pumps, and other j-i pumps are taken as standby pumps; that is, the 1 st pump of the first i previous pumps with the priority order from high to low is the first main pump of the priority order, and the 2 nd pump is the second main pump … … with the priority order, and the ith pump is the ith main pump of the priority order.

S7: the operation status of all the pumps is detected, and if any pump stops operating, the operation returns to S2.

At S2, the operating conditions include: the running times of the pump and whether the pump can work normally are set manually, and the running state handles of the pump are used for main use, standby use or cutting off. The steps of the invention take the three working condition factors as examples, and the working condition factors can be expanded according to the actual application condition in actual application.

The various operating conditions of all pumps are as follows:

in all pumps, if the pump can work normally, the working condition value X is 1; if the pump can not work normally, the working condition value X is 0. Setting the working condition value of the n number of pumps as Xn;

in all the pumps, if the pumps can work normally, the working condition value X is 1; if the pump can not work normally, the working condition value X is 0. The working condition value of the n number pump is set as Xn.

In all pumps, if the operating state of the pump is manually set as 'main use', the value of the state working condition value Y is 2; if the operating state handle of the pump is manually set as 'standby', the working condition value Y of the state is 1; if the operating state handle of the pump is artificially set to be cut off, the state working condition value Y is 0. The reason for taking the value is that the operating state of the pump is manually set to be 'primary' with higher priority than manually set to be 'standby', and manually set to be 'standby' with higher priority than manually set to be 'cut'. And setting the state working condition value of the n number of pumps as Yn.

In all pumps, the running times of the pumps are sequenced, and the pump time working condition values Z corresponding to the times from high to low are sequentially 1, 2 … … 5 and 6. And setting the working condition value of the n number of pumps as Zn.

In S3, the importance of the pump alternation is that: whether the pump can work normally or not, the running state handle of the pump is manually set in a primary mode, a standby mode or a cutting mode, and the running times of the pump are counted;

setting the weight value a of 100 for the normal operation of the pump;

the running state of the pump is characterized in that the weight value b of the handle which is manually set as 'primary', 'standby' or 'cut-off' is 10;

the weighted value c of the number of pump operations is 1.

In S4, the priority score M ═ aX + bY + cZ ═ 100X +10Y + Z is calculated for each pump; the priority score Mn for pump n is 100Xn +10Yn + Zn.

In S5, the pumps are prioritized according to the size of Mn, and as the priority score Mn of the pump n is larger and the priority is higher, the pump n is arranged at the front of the queue, and as Mn1 ≧ Mn2 ≧ Mn3 ≧ Mn4 ≧ Mn5 ≧ Mn6, the priority is as follows: n1, n2, n3, n4, n5 and n 6.

The system pressure is measured by a plurality of pressure sensors, so that redundant measurement is realized, and the stability and reliability of the system are improved. When one sensor fails, a standby sensor can participate in control, and the stability and reliability of the system are improved.

The invention relates to a method for controlling the running state of a hydraulic system of a hydraulic turbine governor, which has the following technical effects:

1) the method of the invention is widely suitable for hydraulic control systems of hydraulic turbine speed regulators with various scales such as small, medium, large and huge hydraulic turbine speed regulators.

2) The method adopts a plurality of sensors of the same type for measurement, realizes redundant measurement and improves the stability and the reliability of the system. When one sensor fails, a standby sensor can participate in control, and the stability and reliability of the system are improved.

3) The method has strong control stability and reliability, and in order to ensure the stability and reliability of the pressure of a hydraulic control system of the speed regulator, a plurality of hydraulic points are adopted to progressively control the starting, the stopping, the loading and the unloading of a plurality of motor oil pumps of the pressure maintenance equipment layer by layer, so that the hydraulic redundancy control is realized, and meanwhile, when the pumps are not loaded and started successfully due to faults or other reasons, the priorities of the pumps are refreshed in turn in time, so that the control logic of starting and standby pumps is realized, the fault-tolerant control is realized, and the pressure stability of the hydraulic control system of the speed regulator is ensured.

Drawings

Fig. 1 is a schematic structural diagram of a hydraulic control system of a hydraulic governor of the present invention.

FIG. 2 is a flow chart of the control method of the present invention.

Fig. 3 is a flow chart of an intelligent queuing alternate working method of a plurality of working pumps and a plurality of standby pumps according to the invention.

Detailed Description

As shown in fig. 1, a hydraulic control system of a hydro governor includes: the system comprises a pressure container 1, a non-pressure container 2, a pressure maintaining device 4, a sensor group 5, a controller 6, a human-computer interaction device 7 and a monitoring system 10;

the pressure container 1 is connected with a plurality of branch pipelines through a main pipeline 3, and an isolation valve 11 is arranged on the main pipeline 3;

any one branch pipeline is connected with a pressure maintaining device 4, and any one branch pipeline is provided with a loading and unloading valve group 12, a filter 13 and an oil inlet valve 14; a plurality of branch pipes are connected to the pressureless container 2;

the pressure vessel 1, the non-pressure vessel 2, the main pipeline 3, the pressure maintaining equipment 4, the isolating valve 11, the loading and unloading valve group 12, the filter 13 and the oil inlet valve 14 are respectively provided with a sensor, a plurality of sensors are all connected to the controller 6, and the controller 6 is respectively connected with the human-computer interaction device 7 and the monitoring system 10.

The pressure container 1 is a pressure oil tank, and the non-pressure container 2 is a non-pressure oil return tank.

The pressure maintaining equipment 4 is n fixed-frequency or variable-frequency motor oil pumps which are respectively numbered as 1#, 2# … … n #.

The sensor group 5 comprises a plurality of sensors, and the sensors are used for respectively acquiring physical quantity parameters or state signals of a pressure container 1, a non-pressure container 2, a main pipeline 3, a pressure maintaining device 4, an isolating valve 11, a loading and unloading valve group 12 and a filter 13 in a hydraulic control system, such as the pressure of the pressure container 1, the pressure of the main pipeline 3, the oil level of the pressure container 1, the oil temperature of the pressure container 1, the running state of the pressure maintaining device 4, the switching position state of the isolating valve 11, the loading and unloading position state of the loading and unloading valve group 12, a filter blockage signal of the filter 13, the switching position state of an oil inlet valve 14 and the like, and transmitting the physical quantity parameters or the state signals to the controller 6 through an electric circuit 8.

The pressure in the main line 3 is the system oil pressure. The oil pressure measurement of the system adopts a pressure sensor with the brand of KELLER and the model number of PA.23SY/100 bar/81594.55. The physical quantity parameters can be measured by a plurality of sensors of the same type, so that redundant measurement is realized, and the stability and reliability of the system are improved. When one sensor fails, a standby sensor can participate in control, and the stability and reliability of the system are improved.

The controller 6 receives a remote control instruction, such as a start-stop hydraulic control system instruction, issued by the monitoring system 10 through the electric circuit 8. Meanwhile, through the communication loop 9, the control parameters of the hydraulic control system set by the human-computer interaction device 7 are received, such as the main 1 pump starting and loading pressure P1, the main 1 pump unloading stop pressure P1 ', the main 2 pump starting and loading pressure P2 and the main 2 pump unloading stop pressure P2 ' … …, the main n pump starting and loading pressure Pn, the main n pump unloading stop pressure Pn ' and the like, and after logical processing is carried out by adopting a hydraulic control system operation state control method of the hydraulic turbine governor according to the hydraulic control system state signals collected by the sensor 5 received through the electrical loop 8, under the hydraulic control system operation state working condition of the hydraulic turbine governor, the start-stop control is carried out on n fixed-frequency or variable-frequency motor oil pumps in the pressure maintaining equipment 4, the on-off control is carried out on the isolating valve 11, the loading-unloading control is carried out on the loading-unloading valve bank 12, and the hydraulic control system state information and fault alarm information are transmitted to the human-computer interaction device through the communication loop 9 7 and a monitoring system 10. The main pump 1 is the pump with the priority ranking of start-stop and unloading control 1, and so on, and the main pump n is the pump with the priority ranking of start-stop and unloading control n. The priority sequencing alternate method of the pumps refers to an intelligent queuing alternate working method of a plurality of working pumps and a plurality of standby pumps. The human-computer interaction device 7 communicates with the controller 6. Comparing the control parameters of the hydraulic control system, such as the rated pressure of the system, the maintenance pressure of the system shutdown and the loading pressure, set by a user through the man-machine interaction device 7 with the standard value P _{Add a}Comparison of the reference value P with the unloading pressure criterion_UnloadingAnd the parameters are transmitted to the controller 6, and meanwhile, the man-machine interaction device 7 acquires the parameter information and the fault alarm information of the hydraulic control system, which are transmitted by the controller 6, and graphical display is carried out.

The sensor group 5, the pressure maintaining equipment 4, the isolating valve 11 and the loading and unloading valve group 12 are connected with the controller 6 through the electric loop 8, so that the transmission of state signals and control signals is realized.

The controller 6 is respectively connected with the human-computer interaction device 7 and the monitoring system 10, and transmission of control parameters, state information, fault alarm information and starting and stopping hydraulic control system commands of the hydraulic control system is achieved.

The pressure maintaining equipment 4 can adopt a three-phase asynchronous variable frequency oil pump motor with the brand of ABB and the model of QABP series, or adopt a fixed frequency oil pump motor with the brand of ABB and the model of M3BP series.

The controller 6 is a PLC controller with the model number of 140CPU67160 and the brand number of Schneider.

The man-machine interaction device 7 adopts a touch screen with the brand name of Schneider and the model number of XBTGT 7340.

The monitoring system 10 is a monitoring system of H9000 type manufactured by a reclaimed water science and technology manufacturer.

The hydropower station main monitoring system is divided into a plant station layer and a local control unit layer on the whole level. The site control unit layer is connected with the power station control network, and the site monitoring task of the specified equipment is completed by adopting a field bus technology. The monitoring system is characterized in that the monitoring system is a site control unit layer which is distributed according to controlled object units and consists of site control units LCUs of a whole plant, wherein the site control units LCUs comprise unit LCUs, service power LCUs, public LCUs, switch station LCUs and dam crest LCUs. Each local control unit LCU comprises a PLC, a touch screen, network equipment, a cabinet and the like and is responsible for equipment data acquisition and processing, equipment state monitoring and process monitoring, equipment control and adjustment and equipment information communication. The equipment comprises speed regulating system equipment.

A method for controlling the running state of a hydraulic system of a hydraulic governor of a hydraulic turbine takes 3 pumps designed in the hydraulic control system of the hydraulic governor as an example, and can be expanded and applied to the situation that n pumps are designed. The method is applied to the oil pump state conversion control of a hydraulic control system of a speed regulator of a certain power station. The system is designed with 3 oil pumps, P1-6.1 Mpa, P2-5.9 Mpa, P3-5.8 Mpa, P1-6.25 Mpa, P2-6.15 Mpa, P3-6.05 Mpa, T1-20 ms, T2-300 ms, T3-300 ms, T4-500 ms, T5-500 ms, T6-500 ms, T1-T2-T3-T4-T5-T6-3 s. The method of the present invention will be described in detail below with reference to this example. The method comprises the following steps:

1. a controller 6 of the hydraulic control system of the speed regulator detects whether the hydraulic control system is in an operating state, if so, the step 2 is carried out; otherwise, continuing the detection of the step.

2. The controller 6 of the hydraulic control system of the speed regulator detects whether the system pressure is less than P1, if so, the step 3 is carried out; if not, returning to the step 1;

detecting whether the system pressure is less than P2, if yes, entering step 11; if not, returning to the step 1;

detecting whether the system pressure is less than P3, if yes, entering step 19; if not, returning to the step 1;

detecting whether the system pressure is greater than P1', if yes, entering step 27; if not, returning to the step 1;

Detecting whether the system pressure is greater than P2', if yes, entering step 30; if not, returning to the step 1;

detecting whether the system pressure is greater than P3', if yes, entering step 33; if not, returning to the step 1.

3. The controller of the hydraulic control system of the speed regulator detects whether the system pressure is less than P1, the system pressure is kept for 20ms, and the main pump 1 is not loaded, if so, the 4 th step is carried out; if not, returning to the step 1.

4. The controller of the hydraulic control system of the speed regulator sends a main pump starting 1 command and enters step 5.

5. The controller of the hydraulic control system of the speed regulator detects whether the time delay 3s of starting the main pump 1 is up, if so, the step 6 is carried out; if not, continuing the detection.

6. The speed regulator hydraulic control system controller detects whether the main pump 1 is started dynamically, if so, the step 7 is carried out; if not, the step 10 is entered.

7. And (5) sending a main 1 pump loading command by a speed regulator hydraulic control system controller, and entering the step 8.

8. A speed regulator hydraulic control system controller detects whether a time delay 3s of a main 1 pump loading command is sent out, if so, the step 9 is carried out; if not, continuing the detection in the step.

9. A speed regulator hydraulic control system controller detects whether a main pump 1 is in a loading state, if so, the step 1 is carried out; if not, sending a main 1 pump stop command, and entering the step 10.

10. And refreshing the priority of the pumps by adopting an intelligent queuing alternate working method of a plurality of working pumps and a plurality of standby pumps, and entering the step 4.

11. The controller of the hydraulic control system of the speed regulator detects whether the system pressure is less than P2, the system pressure is kept for 300ms, and the main pump 2 is not loaded, if so, the step 12 is carried out; if not, returning to the step 1.

12. And (5) sending a main pump 2 starting command by a controller of the hydraulic control system of the speed regulator, and entering the step 13.

13. A controller of a hydraulic control system of the speed regulator detects whether a delay time 3s for starting a main pump 2 is up, if so, the step 14 is carried out; if not, continuing the detection in the step.

14. The controller of the hydraulic control system of the speed regulator detects whether the main pump 2 is started dynamically, if so, the step 15 is carried out; if not, the step 18 is entered.

15. The speed regulator hydraulic control system controller sends out a main 2 pump loading order to enter the next step.

16. A speed regulator hydraulic control system controller detects whether a main pump loading 2 is sent out to delay time for 3s, if so, the step 17 is carried out; if not, the detection is continued.

17. A controller of a hydraulic control system of the speed regulator detects whether a main pump 2 is in a loading state, if so, the step 1 is carried out; if not, a main 2 pump stop command is sent, and the step 18 is entered.

18. And refreshing the priority of the pumps by adopting an intelligent queuing alternate working method of a plurality of working pumps and a plurality of standby pumps, and entering the step 12.

19. The controller of the hydraulic control system of the speed regulator detects whether the system pressure is less than P3, the system pressure is kept for 300ms, and the main 3 pump is not loaded, if so, the 20 th step is carried out; if not, returning to the step 1.

20. The controller of the hydraulic control system of the speed regulator sends out a command of starting a main pump 3 to enter a step 21.

21. A controller of a hydraulic control system of the speed regulator detects whether a delay time 3s for starting a main pump 3 is up, and if so, the step 22 is carried out; if not, continuing the detection.

22. The speed regulator hydraulic control system controller detects whether the main pump 3 is started dynamically, if so, the step 23 is carried out; if not, go to step 26.

23. And (5) sending a main 3-pump loading command by a hydraulic control system controller of the speed regulator, and entering the step 24.

24. A speed regulator hydraulic control system controller detects whether a time delay 3s of a main 3 pump loading command is sent out, if so, the 25 th step is carried out; if not, continuing the detection.

25. A speed regulator hydraulic control system controller detects whether a main pump 3 is in a loading state, if so, the step 1 is carried out; if not, a main 3 pump stop command is sent, and the step 26 is entered.

26. The intelligent queuing alternate working method of a plurality of working pumps and a plurality of standby pumps is adopted to refresh the priority of the pumps and enter the step 20.

27. The controller of the hydraulic control system of the speed regulator detects whether the system pressure is greater than P1', the system pressure is kept for 500ms, the main pump 1 runs or loads, and if yes, the step 28 is carried out; if not, returning to the step 1.

28. And (5) sending out a main pump unloading command 1 by a hydraulic control system controller of the speed regulator, and entering the step 29.

29. The controller of the hydraulic control system of the speed regulator sends out a main pump 1 stopping order and enters the step 1.

30. The controller of the hydraulic control system of the speed regulator detects whether the system pressure is greater than P2', the system pressure is kept for 500ms, and the main 2 pump runs or loads, if yes, the step 31 is carried out; if not, returning to the step 1.

31. The governor hydraulic control system controller sends out the unload main 2 pump order to step 32.

32. The controller of the hydraulic control system of the speed regulator sends out a main 2-pump stopping order and enters the step 1.

33. The governor hydraulic control system controller detects whether the system pressure is greater than P3' for 500ms and the main 3 pump is running or loading, if yes, the 34 th step is entered; if not, returning to the step 1.

34. And (5) sending out a main unloading 3 pump order by a hydraulic control system controller of the speed regulator, and entering the step 35.

35. The controller of the speed regulator hydraulic control system sends out a main 3 pump stopping order and enters the step 1.

As shown in fig. 3, an intelligent queuing alternate working method of multiple working pumps and multiple standby pumps includes the following steps:

step 1: and initializing, and determining the number i of the working pumps of the system and the total number j of the pumps.

Step 2: and collecting multiple working condition factors of all pumps and determining various working condition values of all pumps.

And 3, step 3: and (4) carrying out weight sequencing according to various working condition factors of all the pumps, and determining the weight values of various working condition factors of all the pumps.

And 4, step 4: and calculating the priority score of each pump according to the working condition values corresponding to the various working condition factors of all the pumps and the weight values corresponding to the corresponding working condition factors.

And 5: prioritizing all pumps in the system according to the priority score of each pump;

step 6: according to the priority sequence of all pumps, the first i pumps with the priority sequence from high to low are taken as working pumps, and other j-i pumps are taken as standby pumps; that is, the 1 st pump of the first i pumps with the priority order from high to low is the main 1 pump, the 2 nd pump is the main 2 pump … …, and the ith pump is the main i pump.

And 7: and (5) detecting the running states of all the pumps, and if any pump stops running, returning to the step 2.

In step 2, the multiple working condition factors include: the running times of the pump and whether the pump can work normally are set manually, and the running state handles of the pump are used for main use, standby use or cutting off. The steps of the invention take the three working condition factors as examples, and the working condition factors can be expanded according to the actual application condition in actual application.

The various operating conditions of all pumps are as follows:

In all pumps, if the pump can work normally, the working condition value X is 1; if the pump can not work normally, the working condition value X is 0. Setting the working condition value of the n number of pumps as Xn;

in all pumps, if the pump can work normally, the working condition value X is 1; if the pump can not work normally, the working condition value X is 0. The operating condition value of the n number pump is set as Xn.

In all pumps, if the operating state of the pump is manually set as 'main use', the value of the state working condition value Y is 2; if the operating state handle of the pump is manually set as 'standby', the working condition value Y of the state is 1; if the operating state handle of the pump is artificially set to be cut off, the state working condition value Y is 0. The reason for taking the value is that the operating state of the pump is manually set to be 'primary' with higher priority than manually set to be 'standby', and manually set to be 'standby' with higher priority than manually set to be 'cut'. And setting the state working condition value of the n number of pumps as Yn.

In all the pumps, the operation times of the pumps are sequenced, and the pump time working condition values Z corresponding to the times from high to low are sequentially 1, 2 … … 5 and 6. And setting the working condition value of the number n of pumps as Zn.

In the step 3, the importance of three factors considered by the pump alternation is that: whether the pump can work normally or not, the running state handle of the pump is manually set in a primary mode, a standby mode or a cutting mode, and the running times of the pump are counted;

Setting the weight value a of 100 for the normal operation of the pump;

the running state of the pump is characterized in that the weight value b of the handle which is manually set as 'primary', 'standby' or 'cut-off' is 10;

the weighted value c of the number of pump operations is 1.

In the step 4, the priority score M ═ aX + bY + cZ ═ 100X +10Y + Z is calculated for each pump; the priority score Mn for pump n is 100Xn +10Yn + Zn.

In step 5, the pumps are prioritized according to the size of Mn, and if Mn1 ≧ Mn2 ≧ Mn3 ≧ Mn4 ≧ Mn5 ≧ Mn6, the priority is as follows: n1, n2, n3, n4, n5 and n 6.

Claims (5)

1. An intelligent queuing alternate working method for a plurality of working pumps and a plurality of standby pumps is characterized by comprising the following steps:

s1: initializing, and determining the number i of working pumps and the total number j of pumps of the system;

s2: collecting multiple working condition factors of all pumps, and determining various working condition values of all pumps;

s3: according to various working condition factors of all pumps, carrying out weight sequencing and determining the weight values of various working condition factors of all pumps;

s4: calculating the priority score of each pump according to the working condition values corresponding to various working condition factors of all pumps and the weight values corresponding to the corresponding working condition factors;

S5: prioritizing all pumps in the system according to the priority score of each pump;

s6: according to the priority sequence of all pumps, the first i pumps with the priority sequence from high to low are taken as working pumps, and other j-i pumps are taken as standby pumps; that is, the 1 st pump of the first i pumps with the priority order from high to low is the first main pump of the priority order, the 2 nd pump is the second main pump … … with the priority order, the ith pump is the ith main pump of the priority order;

s7: the operation states of all the pumps are detected, and if any pump stops operating, the operation returns to S2.

2. The intelligent queuing alternate working method for the working pumps and the standby pumps as claimed in claim 1, wherein: at S2, the plurality of operating condition factors include: the running times of the pump, whether the pump can work normally or not, and the running state of the pump is manually set by a handle of 'main use', 'standby' or 'cut';

the various operating conditions of all pumps are as follows:

in all the pumps, if the pumps can work normally, the working condition value X is 1; if the pump can not work normally, the value of the working condition value X is 0; setting the working condition value of the n number of pumps as Xn;

in all pumps, if the operating state handle of the pump is manually set as 'main use', the working condition value Y of the state takes the value of 2; if the operating state handle of the pump is manually set as 'standby', the working condition value Y of the state is 1; if the operating state handle of the pump is artificially set to be cut off, the state working condition value Y is 0; the reason for taking the value is that the operating state of the pump is manually set to be 'main' with higher priority than manually set to be 'standby', and manually set to be 'standby' with higher priority than manually set to be 'cut'; setting the state working condition value of the n number pump as Yn;

In all the pumps, the running times of the pumps are sequenced, and the corresponding pump time working condition values Z from high to low are sequentially 1, 2 … … 5 and 6; and setting the working condition value of the n number of pumps as Zn.

3. The intelligent queuing alternate working method for the working pumps and the standby pumps as claimed in claim 1, characterized in that: at S3, the importance of the three factors considered by the pump alternation is from high to low: whether the pump can work normally or not, the running state of the pump is manually set by a handle of primary use, standby use or cutting-off, and the running times of the pump are counted;

setting the weight value a of whether the pump can work normally as 100;

the operating state of the pump is that the weight value b of the handle which is manually set as 'primary', 'standby' or 'cut-off' is equal to 10;

the weighted value c of the number of pump operations is 1.

4. The intelligent queuing alternate working method for the working pumps and the standby pumps as claimed in claim 1, wherein: in S4, the priority score M ═ aX + bY + cZ ═ 100X +10Y + Z is calculated for each pump; the priority score Mn for pump n is 100Xn +10Yn + Zn.

5. The intelligent queuing alternate working method for the working pumps and the standby pumps as claimed in claim 1, wherein: in S5, the pumps are prioritized according to the size of Mn, and as the priority score Mn of the pump n is larger and the priority is higher, the pump n is arranged at the front of the queue, and as Mn1 ≧ Mn2 ≧ Mn3 ≧ Mn4 ≧ Mn5 ≧ Mn6, the priority is as follows: n1, n2, n3, n4, n5 and n 6.

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