JP2004353220A - Stormwater drainage controlling device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a stormwater drainage controlling device capable of ensuring sufficient reliability as the whole device even if there is in a state to lose reliability of a model while the model is used to have control over the stormwater drainage, systematically handling a hybrid control system wherein a continuous time phenomenon is intermingled with a discrete time phenomenon and eliminating a control destabilizing factor such as an occurrence of a discontinuous phenomenon or the like. <P>SOLUTION: When, for example, J1 is selected from among stormwater drainage controlling amount operation sections J1, J2, etc. and JT, a predetermined estimate (for example, stormwater flow) is calculated by the predictive model 13, a predetermined controlling amount (for example, the number of pump operator's seats and the number of revolutions of the pump) is calculated on the basis of the result by a control model 14. When a control selecting section 15 decides that the reliability of the operation section J1 is impaired during the operation, the selection of the operation section J1 can be immediately stopped. Each evaluation function of other operation sections J2, etc. and JT is calculated by the optimal control evaluation means 16, and the smallest value of the evaluation function is selected among of them. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a rainwater drainage control device used for a rainwater drainage system such as a sewer system.
[0002]
[Prior art]
Due to the recent increase in local torrential rain and the sharpening of runoff due to urbanization, the response to rainwater drainage has been delayed and the possibility of flood damage has increased. In addition, a rapid inflow during a heavy rain is often handled by switching automatic control of the rainwater pump to manual operation by an operator, and the burden on the operator is also increasing. On the other hand, there is also a problem of a chronic shortage of operators, and the shortage of operators has caused a remarkable burden on the operators in rainy weather.
[0003]
Here, the following reasons can be cited as causes of an increase in the burden on the operator. That is, in the conventional rainwater drainage control technology, the pump rotation speed is often controlled only by the water level of the pump well, and the pump well water level detected by the pump well water level detector is set to a preset pump well target water level. The rotation speeds of the respective pumps are controlled by PID control or the like so as to match. Then, since the pump well target water level is a fixed value set in advance, when the pump well capacity is small and the water level controllable range is small, the start and stop of the second and subsequent pumps frequently occur. . In addition, when the inflow into the rainwater pump well suddenly increases due to heavy rain, even if one new pump is started due to a delay in starting the pump, the water level cannot keep up with the rising water level, and the pump well water level reaches the dangerous water level. It can be lost. For this reason, in most cases, in practice, the skilled operator relies on manual operation by a skilled operator without using automatic control.
[0004]
Due to the above reasons, the burden on the operator has increased, and the number of operators has been insufficient. Therefore, it is desired to realize a rainwater drainage control technology that can cope with a sudden inflow of rainwater and that can cope with the current shortage of personnel and labor saving or unmanned pump stations in the future. .
[0005]
By the way, in rainwater drainage control, if the information of "when and how much rainwater flows in" can be accurately grasped at the pump station, it is also possible to accurately grasp the appropriate start / stop timing of the rainwater pump. . Various types of information for grasping the appropriate timing include measured values obtained from radar rain gauges, ground rain gauges, water gauges in sewers, etc. Has been done. Conventionally, pump automatic control utilizing such outflow analysis and inflow amount prediction has been performed.
[0006]
As a method for predicting the amount of rainwater inflow, a hydraulic approach using a white-box approach (extended RRL method, general-purpose runoff analysis software (MOUSE, etc.)) that tracks the temporal change of rainfall runoff using a physical model or a conceptual model Models and hydrological models) and black-box approaches (based on system identification methods, multiple regression analysis, etc.) that build predictive models only from past rainfall and inflow data.
[0007]
Here, the extended RRL method is disclosed in, for example, Patent Literature 1, and the inflow prediction using the system identification method is disclosed in, for example, Patent Literature 2. The pump control based on the inflow amount prediction result includes, for example, a prediction control in which the set water level is changed using the inflow amount prediction value, based on the set water level automatic control. This is proposed in Patent Document 3 as a method for predicting and calculating the number of pumps to be operated based on the amount of rainwater flowing into a pump well and the pump rating. In recent years, a system for predicting rainwater inflow and controlling a rainwater pump using overseas general-purpose software (such as MOUSE) has been spreading in Japan. Although general-purpose software was originally used offline as a rainwater runoff analysis simulator, it has become possible to operate it online by linking it with a monitoring and control system.
[0008]
As described above, the predictive control technique utilizing the inflow rate prediction is effective for realizing automatic control of rainwater drainage, and various methods have been used. It is increasingly important to achieve these techniques appropriately and accurately according to the situation.
[0009]
[Patent Document 1]
JP-A-6-147940
[Patent Document 2]
JP 2000-257140 A
[Patent Document 3]
JP 2000-328642 A
[0010]
[Problems to be solved by the invention]
As described above, the prediction control technology utilizing the inflow estimation is effective for realizing automatic rainwater drainage control, and its methods have been wide-ranging. It is increasingly important to achieve these techniques appropriately and accurately according to the situation. However, in most cases, rainwater drainage control based on the predicted inflow amount by these prediction models is performed by mounting only one prediction model and one control model. Therefore, when the reliability of the mounted prediction model itself and control model itself is impaired, it is no longer possible to continuously perform automatic control. In such a case, the operation mode must be switched from the automatic control mode to the manual operation mode, and the burden on the operator becomes remarkable.
[0011]
One of the objectives of achieving full automation of stormwater drainage control is to reduce the number of personnel in stormwater drainage control, which is currently performed by deploying a large number of personnel. In the case of the rainwater drainage control device in which only one type is mounted, if the reliability is low, the automatic control is not established and the purpose cannot be achieved. As described above, in recent years, rainwater drainage control devices incorporating overseas general runoff analysis software represented by “MOUSE” have attracted attention, and demand has been increasing. The effectiveness of general-purpose runoff analysis software has been confirmed in offline analysis, but its effectiveness online has not been fully evaluated. Therefore, when using a rainwater drainage control system that incorporates general runoff analysis software online, implement a control device that uses a different method to evaluate its reliability, and improve its control performance. Evaluation is also necessary for safe automatic control. In other words, even if the reliability of this software is lost while the control is being executed using a certain software (or model), if it is possible to immediately switch to another software, the device or system as a whole will suffice. Although high reliability can be ensured, a device or system based on such an idea has not heretofore appeared.
[0012]
The rainwater drainage control device performs, for example, determination of the number of pumps operated based on the amount of inflow of rainwater, control of the number of pumps based on this determination, control of the number of pump rotations, and the like. The number of operating pumps is a discrete-time event. As described above, a system in which control for continuous time events and control for continuous time events coexist is called a hybrid control system. Many of the control systems in actual processes are hybrid control systems, and such hybrid control systems are found everywhere, such as in cars, airplanes, appliances, and chemical plants.
[0013]
Although the hybrid control system is employed in many of the control systems of the actual process as described above, it has hardly been systematically handled in the past. If a control system is constructed without considering a hybrid control system, a discontinuous phenomenon may occur in a mixed portion of a continuous time system and a discrete time system. This discontinuous phenomenon appears as a behavior such as frequent repetition of pump start / stop and vibration in the rotation speed control, and this behavior makes the rainwater drainage control system unstable and automatic control cannot be realized. Therefore, it is necessary for the operator to switch the automatic control mode to the manual operation mode and operate the pump and the like, resulting in an increased burden on the operator.
[0014]
The present invention has been made in view of the above circumstances, and even if the reliability of this model is lost while performing control using a certain model, sufficient reliability as the entire device is obtained. Stormwater drainage control that enables systematic handling of hybrid control systems in which continuous-time events and discrete-time events coexist, and eliminates control instability factors such as the occurrence of discontinuous phenomena It is intended to provide a device.
[0015]
[Means for Solving the Problems]
As means for solving the above problems, the invention according to claim 1 includes a prediction model for calculating a predicted amount of a predetermined object based on input of process data, and a predetermined object based on the predicted amount calculated by the prediction model. A plurality of rainwater drainage control amount calculation units each comprising a control model for calculating a control amount of equipment, and each control performance of the plurality of rainwater drainage control amount calculation units is evaluated, and an optimum control performance is obtained based on the evaluation. And a process control unit that controls the predetermined target device based on a calculation result of the rainwater drainage control amount calculation unit selected by the control selection unit. And
[0016]
According to a second aspect of the present invention, in the first aspect of the present invention, the control selecting unit performs the evaluation and the selection when another error occurs in the currently selected rainwater drainage control amount calculation unit. It is performed for a plurality of rainwater drainage control amount calculation units.
[0017]
According to a third aspect of the present invention, in the first or second aspect, the control selection unit performs the evaluation and the selection at predetermined intervals.
[0018]
The invention according to claim 4 is the invention according to any one of claims 1 to 3, wherein the prediction model calculates the prediction amount based on a white box approach or a black box approach. It is characterized by the following.
[0019]
According to a fifth aspect of the present invention, in the invention according to any one of the first to fourth aspects, parameters of the prediction model or the control model of the stormwater drainage control amount calculation unit are updated online based on process data. , Is characterized.
[0020]
According to a sixth aspect of the present invention, in the invention according to any one of the first to fifth aspects, the rainwater drainage control amount calculation unit uses at least one of an operation time, an operation cost, and an operation amount as an index. The calculation of the optimal control amount is performed.
[0021]
According to a seventh aspect of the present invention, in the invention of the sixth aspect, the rainwater drainage control amount calculation unit calculates the optimum control amount using Receiving horizon control in which a constraint condition is applied to a predetermined control amount. Is characterized by the following.
[0022]
The invention according to claim 8 is characterized in that, in the invention according to claim 6, the rainwater drainage control amount calculation unit calculates the optimum control amount using a branch and bound method.
[0023]
A ninth aspect of the present invention is characterized in that, in the sixth aspect of the present invention, the rainwater drainage control amount calculation unit calculates the optimum control amount using a genetic algorithm.
[0024]
According to a tenth aspect of the present invention, in the invention of the sixth aspect, the rainwater drainage control amount calculation unit calculates the optimum control amount in consideration of rainfall information from a rainfall radar or a ground-based rain gauge. , Is characterized.
[0025]
According to an eleventh aspect of the present invention, in the invention according to any one of the first to tenth aspects, the stormwater drainage control amount calculation unit determines a control value relating to a discrete time event based on a continuous time event value or a discrete time event. Determining a control value for a continuous-time event based on the value, and determining the control value by using an auxiliary variable relating the continuous-time event to the discrete-time event. And
[0026]
According to a twelfth aspect of the present invention, in the invention according to the eleventh aspect, the control value relating to the discrete time event based on the continuous time event value is a pump operation number based on the amount of rainwater inflow, and the discrete time event value The control value for the continuous time event based on the number of pump operations is a pump rotation speed.
[0027]
BEST MODE FOR CARRYING OUT THE INVENTION
FIG. 1 is an explanatory diagram showing a configuration of a rainwater drainage control system using a rainwater drainage control device according to an embodiment of the present invention. The rainwater flowing into the inflow main line 1 passes through the inflow channel 2 and is stored in a pump well 4 partitioned by an inflow gate 3. A plurality of rainwater pumps P1, P2,..., PM are provided in the pump well 4, and discharge valves V1, V2,. Water level gauges WL1 and WL2 are provided before and after the inflow gate 3, and the rainwater drainage control device 5 receives rainwater pumps P1, P2,..., PM and discharge valves V1 and V2 based on detection signals from these water level gauges. ,..., VM are discharged to discharge rainwater stored in the pump well 4 toward a river or the like.
[0028]
The measurement data from the above-ground rain gauge 6 is input to the rainwater drainage control device 5. A rainfall radar data processing device 8 is connected to the rainwater drainage control device 5 via a transmission line 7 so that rainwater measurement data from the rainfall radar 9 is input. A monitoring control device 10 is also connected to the transmission line 7, and the operator monitors the rainwater drainage control system via the monitoring control device 10.
[0029]
Next, the operation of FIG. 1 will be described. The rainwater drainage control device 5 predicts rainwater inflow into the pump station, pump well inflow, pump well water level, etc., based on input of measurement data from the ground rain gauge 6 and data from the rainfall radar data processing device 8. In this case, it is possible to make a prediction based only on the data from the ground rain gauge 6, but it is not possible to make a prediction with sufficient accuracy, and the prediction ahead of about 10 to 15 minutes is the limit. I think that the.
[0030]
However, in the configuration of FIG. 1, the rainfall radar data processing device 8 performs various data processing on the observation data from the rainfall radar 9 and outputs the data to the rainwater drainage control device 5. Although not shown in FIG. 1, a weather information terminal or the like is connected to the transmission line 7, and a rainfall situation such as a rainfall amount and a rainfall intensity is predicted from a weather service center or the like. Predict rainwater inflow. According to such a configuration, prediction from 30 minutes to several hours ahead can be performed, and the reliability of rainwater drainage control can be further improved.
[0031]
In addition, the weather mode is determined using the above-mentioned rainfall status prediction and weather information, the predicted inflow amount, various prediction information such as the predicted water level, or their current values, and rainwater drainage control is performed based on the determined weather mode. It is also possible. For example, when it is determined from the various information that the mode is the light rain mode, the rainwater drainage is not immediately performed, and the gate is controlled, and the rainwater at the time of rainfall is taken into the augmented trunk line or the storage pipe installed in advance. Thereby, it is possible to perform an operation of suppressing initial rainwater (first flush) having a high concentration of pollutants from flowing into a treatment plant or a pumping plant. On the other hand, when it is determined that the mode is not the light rain mode, or when the water level of the pump well has reached a specified value or more, the rainwater drainage control is immediately performed. As described above, by changing the mode and performing rainwater drainage control using various types of prediction information, it is possible to cope with the problem of improving the combined sewerage system, which has recently been regarded as important.
[0032]
FIG. 2 is a block diagram showing a detailed configuration of the rainwater drainage control device 5 in FIG. The rainwater drainage control device 5 includes: a process data input unit 11 for inputting process data from the target device O via an online signal line L; a process data quality determination unit 12 for determining the quality of the input process data; .., JT in which a model 13 and a control model 14 are respectively provided, and an optimal control evaluation means 16 are provided therein, and these calculation units J1, J2, , JT, and a process control unit 17 that controls the target device O based on the operation result of the selected operation unit. Further, the operator can manually operate the target device O using the manual operation means 18. The manual operation means 18 may be dedicated hardware, or may be software operated via the monitoring control device 10. The target equipment O refers to the rainwater pumps P1, P2, ..., PM, the discharge valves V1, V2, ..., VM, and the inflow gate 3 and the like, and is connected to the process data input unit 11 via the signal line L. The signals to be transmitted include signals related to these target devices, such as the water level gauges WL1 and WL2, in addition to the signals related thereto.
[0033]
Next, the operation of FIG. 2 will be described. The process data input unit 11 inputs process data from the target device O via the online signal line L, and outputs the process data to the process data pass / fail determination unit 12. Then, the process data pass / fail determination unit 12 determines pass / fail of the process data. For example, if a certain data value shows an abnormal value over a certain number, the process data acceptability judgment unit 12 displays this abnormality on the monitoring and control device 10, and the operator stops automatic control immediately after seeing the abnormality display. Then, manual operation is performed using the manual operation means 18.
[0034]
In the configuration of FIG. 2, T rainwater drainage control amount calculation units J1, J2,..., JT are provided as having a function of calculating the rainwater drainage control amount. When the system is started, one of the T rainwater drainage control amount calculation units J1, J2,..., JT used by the control selection unit 15 is selected in advance by the control selection unit 15. The selection criteria in this case include, for example, the shortest operation time, the lowest operation cost, the lowest operation amount (the minimum number of times of switching the number of operating pumps), and the like. .
[0035]
Now, for example, if the rainwater drainage control amount calculation unit J1 is selected, the prediction model 13 of the calculation unit J1 determines a predetermined prediction amount (for example, rainwater inflow) based on the data input via the process data quality determination unit 12. ), And the control model 14 calculates a predetermined control amount (for example, the number of operating pumps and the number of rotations of the pump) based on the calculated predicted amount. The calculated control amount is output to the process control unit 17 via the control selection unit 15, and the process control unit 17 performs the process control on the target device O based on the input control amount.
[0036]
If the control selector 15 determines that the reliability of the rainwater drainage control amount calculator J1 has been impaired during the execution of the operation control for the system, the control selector 15 immediately selects the rainwater drainage control amount calculator J1. Try to stop. Here, as to whether or not the reliability has been impaired, for example, it is determined whether or not the value of the evaluation function for the operation time, operation cost, or operation amount calculated by the optimal control evaluation means 16 has become larger than a certain value. It can be done by doing. Next, the optimal control evaluation means 16 calculates each evaluation function of the rainwater drainage control amount calculation units J2,..., JT, and selects the rainwater drainage control amount calculation unit in which the value of the evaluation function is the smallest. I do.
[0037]
According to the above configuration, since a plurality of types of software having a function of calculating the amount of rainwater drainage control are prepared in advance, while one of them is selected and the operation control is executed, the Even if the reliability of the selected software is impaired, the optimum software can be immediately selected from other software and the operation control can be continued without stopping.
[0038]
Each of the prediction models 13 in the rainwater drainage control amount calculation units J1, J2,..., JT may employ either software that performs a white-box approach or software that performs a black-box approach. it can. Examples of software that performs a white-box approach include “MOUSE” which is a commercially available package software for outflow analysis that predicts pumping station inflow. Others include the extended RRL method, hydraulic model, and hydrology model. A runoff analysis model based on the above may be adopted. On the other hand, as software for performing a black box approach, there is a model based on a system identification method for predicting pumping station inflow, but a model based on multiple regression analysis or a neural network may be employed.
[0039]
In addition, for various parameters used by the prediction model 13, the control selection unit 15 sets each measurement data from the water level gauges WL1 and WL2, the ground rain gauge 6, and the rainfall radar data processing device 8, or the rainwater pumps P1, P2,. Offline determination can be made in advance based on data on the operation status of the PM, the inflow gate 3 and the like. However, according to the configurations of FIGS. 1 and 2, since the control selecting unit 15 can fetch these data online, it is possible to sequentially update the parameters of the prediction model 13. As described above, by sequentially updating the prediction model 13 online, the model can be updated according to the change of the basin, and the deterioration of the prediction accuracy can be suppressed.
[0040]
As a typical method for sequentially updating the prediction model 13 online, a sequential least squares method in a system identification method is known. This sequential least squares method has a small computational load, can be implemented on a relatively small-scale computer, and has the advantage that model parameters can be updated following process fluctuations. There are no examples of actual use in the field of control. However, for a system such as a rainwater drainage process in which process fluctuations are likely to occur as a result of a complex factor of natural phenomena and are likely to cause fluctuations, a means for sequentially updating the prediction model 13 online as described above is provided. Is very effective.
[0041]
The control model 14 in the present embodiment performs pump control on the inflow amount predicted by the prediction model 13. As a pump control method, the pump operation number may be directly determined based on the inflow rate prediction value, or a pump well water level prediction model in which the inflow rate prediction value is input and the pump well water level prediction value is output is separately constructed, A configuration in which the number of pumps operated is determined based on the predicted value of the pump well water level may be adopted. Although the set water level automatic control using the fixed pump well water level set value has been conventionally performed, the control model 14 in the present embodiment corrects the set water level based on the predicted inflow amount from the prediction model 13. The start timing or the stop timing of the pump can be appropriately changed based on the corrected set water level.
[0042]
FIG. 3 is an explanatory diagram of such correction of the set water level in the present embodiment. In this figure, the tail end position and the tip position of each arrow indicate the start water level and the stop water level of the corresponding pump. That is, for example, the pumps P3 and P4 of the four rainwater pumps P1 to P4 were initially set to have a starting water level of 2.60 m and 2.75 m, respectively, and a stop water level of 2.20 m and 2.40 m, respectively. However, the control model 14 moves each of the start water level and the stop water level downward by 0.05 m based on the inflow amount predicted value of the prediction model 13 thereafter. With such a configuration, it is possible to perform fine control according to the change state of the process.
[0043]
Further, in the above-described embodiment, when the reliability of the selected rainwater drainage control amount calculation unit J1 is impaired, the control selection unit 15 newly selects from the other calculation units J2,..., JT. Although the example has been described, the control selection unit 15 calculates all the evaluation functions of the rainwater drainage control amount calculation units J1, J2,..., JT by the optimum control evaluation unit 16 at predetermined intervals, and determines the reliability of the calculation unit J1. Even if it does not decrease to a level that impairment has been impaired, a configuration may be adopted in which if there is another operation unit having a smaller evaluation function, that operation unit is selected.
[0044]
That is, the control selection unit 15 selects a rainwater drainage control amount calculation unit having a model of the optimal control performance at every predetermined cycle (in accordance with operation), and outputs the output of the calculation unit to the process control unit 17. Output to perform optimal rainwater drainage control. Then, when the selected arithmetic unit is not optimal or when it is determined that it does not operate normally based on the result of abnormality diagnosis such as sensor value abnormality, the operation of automatically switching to another arithmetic unit is immediately performed. Do. As described above, since the control selection unit 15 can quantitatively evaluate the control problem of the rainwater drainage process by solving the optimal control problem, it is possible to level the pump operation time and reduce the number of operation switching. Performing the above-described control performance determination (determination based on abnormality diagnosis and determination based on the evaluation function value) leads to high reliability of rainwater drainage control, and enables stable automatic control operation.
[0045]
Here, conventionally, when performing control performance determination offline, it is time-consuming to perform the determination work once separated from the system and then re-integrated into the system, and it is necessary to continue automatic control at an unmanned pumping station. There is a problem that it cannot be dealt with in such cases. However, in the above embodiment, since the control performance determination can be performed online, such a problem does not occur. In the past, there has been no example dealing with the optimal control problem including such costs in the rainwater drainage control problem, and the method according to the present embodiment can be said to be an effective method.
[0046]
For example, Receiving Horizon control, which is known as a basic concept of model predictive control, can be applied to the configuration of an optimal control system that handles the above-described optimal control problem. The Receiving Horizon control is a control that repeats online optimization while shifting a section for solving an optimization problem for each sampling period, and can handle constraints in an explicit manner. That is, there is an advantage that the constraint conditions concerning the control input and the process output can be directly reflected in the control algorithm. In this case, the given rainwater drainage control problem can be reduced to an optimization problem including the constraint condition by considering the upper and lower limits of the pump well water level as the constraint condition.
[0047]
As a technique for solving the above-described optimal control problem, application of a branch and bound method, a genetic algorithm, or the like can be considered. The branch-and-bound method collectively checks subspaces in a solution space and verifies in advance whether solution candidates can exist in the space, thereby eliminating unnecessary search procedures in advance, and reducing computation time. Has such an advantage that an optimal solution can be searched for. The genetic algorithm can search only a suboptimal solution instead of an optimal solution, but has advantages such as being hard to fall into a local minimum solution and expecting high-speed operation.
[0048]
As described above, by applying the model predictive control, that is, Receiving horizontal control, to the combined rainwater drainage control problem, the control system can be systematically handled, and the rainwater drainage control is always performed by the control device having the optimal control performance. Since it can be performed, it can be expected to establish a rainwater drainage automatic control system capable of leveling the pump operation time, reducing the number of times of operation switching, and solving the problem of manual operation by the operation operator.
[0049]
Next, another embodiment of the present invention will be described. As described above, a system in which control of continuous-time events and control of discrete-time events coexist is called a hybrid control system. In the field of stormwater drainage control, such a hybrid control system is constructed systematically. Had never appeared before. Therefore, in the present embodiment, a configuration in which this hybrid system is systematically constructed is adopted.
[0050]
FIG. 4 is a block diagram showing a specific configuration example of a rainwater drainage control amount calculation unit J1 which is a main part of another embodiment (other calculation units J2,..., JT other than J1 have the same configuration. is there). As shown in this figure, the rainwater drainage control amount calculation unit J1 includes an inflow amount prediction model 13A, a pump operation number determination control unit 14A, a pump well water level setting unit 14B, and a pump rotation speed control unit 14C. Further, it has variable definition sections 19 and 20 and a subtractor 21.
[0051]
FIG. 5 is a flowchart showing the outline of the function of the rainwater drainage control amount calculation unit J1. The inflow rate prediction model 13A inputs the process data determined as good from the process data quality determination unit 12, and predicts the rainwater inflow rate Q (continuous time event value) based on the process data (step 1). Upon input of the predicted continuous-time event value rainwater inflow Q, the variable definition unit 19 defines an auxiliary variable δ for converting the continuous-time event value into a discrete-time event value (Step 2). The auxiliary variable δ and the rainwater inflow amount Q are output to the pump operation number determination control unit 14A. The pump operation number determination control unit 14A calculates the required number of pump operation N by applying the input auxiliary variable δ and rainwater inflow amount Q to a predetermined arithmetic expression (step 3). In other words, the pump operation number determination control unit 14A can use the auxiliary variable δ to treat the pump operation number N as a continuous time system variable based on the input of the rainwater inflow Q which is a continuous time event value. Converted to event values.
[0052]
Further, when the variable defining unit 20 receives the number of pump operation N which is a discrete time event value from the pump operation number determination control unit 14A, the variable defining unit 20 defines an auxiliary variable γ for converting the discrete time event value into a continuous time event value. Then, the auxiliary variable γ and the number of pumps operated N are output to the pump speed controller 14C (step 4). At this time, the difference between the set value from the pump well water level setting unit 14B and the detection value from the water level gauge WL2 is output from the subtractor 21 to the pump rotation speed control unit 14C. The pump rotation speed control unit 14C applies the auxiliary variable γ and the number of pumps operated N input from the variable definition unit 20 to a predetermined arithmetic expression while considering the deviation from the subtractor 21, and calculates the pump rotation speed R. Calculation is performed (step 5). That is, by using the auxiliary variable γ, the pump rotation speed control unit 14C treats the number of pump operations N, which is a discrete time event value, as a variable of a continuous time system, and treats this as a continuous time event value, the pump rotation speed R. Converting.
[0053]
Next, a specific example of a method of calculating the pump operation number N from the rainwater inflow amount Q, which is a continuous time event value, using the auxiliary variable δ in the rainwater drainage control amount calculation unit J1 of FIG. 4 will be described. When the amount of rainwater inflow at a certain time t is Q (t) and the amount of rainfall as process data is u (t), the amount of rainwater inflow Q (t + 1) at time t + 1 is expressed by Expression (1), and Let us consider a system in which the pump operation number N (t) is directly obtained from the rainwater inflow amount Q (t) using the equations (2) to (4). Here, a and b are parameters, which can be determined in advance offline, or can be determined online while sequentially changing them. Although units are omitted in equations (1) to (4), Q (t) and u (t) are, for example, [m3 / s: cubic meter per second], and N (t) is [unit]. .
Q (t + 1) = a * Q (t) + b * u (t) (1)
N (t) = 1 if Q (t) ≦ 3 (2)
N (t) = 2 if 3 <Q (t) ≦ 6 (3)
N (t) = 3 if 6 <Q (t) (4)
[0054]
Since the relationship between N (t) and Q (t) in the above equations (2) to (4) is a relationship between continuous value input and discrete value output, the rainwater drainage control amount calculation unit J1 in FIG. By introducing auxiliary variables into the relationship, the output is transformed into a form that can be treated as a continuous variable. As a specific method of introducing the auxiliary variable, for example, an MLD (Mixed Logical Dynamic) system can be considered. The MLD system is a method for expressing a dynamic system including a logical description, in which discrete events included in a process are represented by logical variables. In the formulation, a logical expression is represented by a linear inequality. It is.
[0055]
By using this concept of the MLD system for the relationship between the predicted inflow amount or the predicted pump well water level and the number of pumps operated, the discrete output can be associated as a continuous variable. Now, when a discrete value auxiliary variable δi (i = 1, 2, 3) is introduced in order to associate the discrete value output with the output as a continuous variable, the variable definition unit 19 calculates this δi by the equations (5) to (7). Is defined as
δ1 = 1 if Q (t) ≦ 3 (5)
δ2 = 1 if Q (t) ≦ 6 (6)
δ3 = 1 (7)
[0056]
When the auxiliary variable δi (i = 1, 2, 3) defined in this way is used, the pump operation number determination control unit 14A determines the output pump operation number N (t) as an MLD system as shown in equation (8). As a continuous time expression of
N (t) = 1 · δ1 (t) + 2 · {δ2 (t) −δ1 (t)} + 3 · {δ3 (t) −δ2 (t)} (8)
[0057]
By substituting specific numerical values into the above equations (5) to (8), for example, when Q (t) = 2, δ1, δ2, δ3 in the equations (5) to (7) are respectively δ1 = 1, δ2 = 1, δ3 = 1, so N (t) in equation (8) is N (t) = 1 · 1 + 2 · (1-1) + 3 · (1-1) = 1 + 0 + 0 = 1 [Table].
[0058]
Similarly, for example, when Q (t) = 4, δ1, δ2, and δ3 in the equations (5) to (7) are δ1 = 0, δ2 = 1, and δ3 = 1, respectively. N (t) is N (t) = 1.0 + 2. (1-0) +3. (1-1) = 0 + 2 + 0 = 2 [units].
[0059]
Also, for example, when Q (t) = 7, δ1, δ2, δ3 in the equations (5) to (7) are δ1 = 0, δ2 = 0, δ3 = 1, respectively. N (t) is N (t) = 1.0 + 2. (0-0) +3. (1-0) = 0 + 0 + 3 = 3 [units].
[0060]
The above example describes the case where the pump operation number determination control unit 14A outputs the discrete time event value N based on the input of the continuous time event value Q. However, the pump rotation speed control unit 14C outputs the discrete time event value N. The case where the continuous-time event value R is output based on the input of N in the above manner can be similarly considered.
[0061]
Therefore, since the above-mentioned stormwater drainage control system is a continuous time system, a system in which it was not easy to construct a control system systematically until now by being a hybrid system can be systematically handled in the present invention. . Therefore, there are problems such as repetition of operation and stop of the pump, instability of rotation speed control caused by the mixture of the continuous time system and the discrete time system, and an increase in operator's burden due to manual operation intervention accompanying these. Can be expected to be reduced.
[0062]
In the above-described embodiment, an example has been described in which the rainwater drainage process in the rainwater drainage pump station is targeted as a specific process, but the idea of the above-described embodiment can be applied to other processes. For example, the present invention is particularly effective for a process using pump control, such as a process for draining rainwater to a river using river water level prediction at a drainage pump station.
[0063]
【The invention's effect】
As described above, according to the present invention, even if the reliability of this model is lost while performing control using a certain model, sufficient reliability of the entire apparatus is ensured. be able to. In addition, a hybrid control system in which continuous time events and discrete time events coexist can be systematically handled, and control instability factors such as occurrence of discontinuous phenomena can be eliminated.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram showing a configuration of a rainwater drainage control system using a rainwater drainage control device according to an embodiment of the present invention.
FIG. 2 is a block diagram showing a detailed configuration of a rainwater drainage control device 5 in FIG.
FIG. 3 is an explanatory diagram of correction of a set water level performed by a control model 14 in FIG. 2;
FIG. 4 is a block diagram showing a specific configuration example of a rainwater drainage control amount calculation unit J1 which is a main part of another embodiment of the present invention.
FIG. 5 is a flowchart showing an outline of functions of a rainwater drainage control amount calculation unit J1 in FIG. 4;
[Explanation of symbols]
1 inflow main line
2 Inflow culvert
3 inflow gate
4 pump well
5 Rainwater drainage control device
6 ground rain gauge
7 Transmission line
8 Rainfall radar data processor
9 Rainfall radar
10 Monitoring and control equipment
11 Process data input section
12 Process data pass / fail judgment unit
13 Prediction model
13A Inflow prediction model
14 Control Model
14A Pump operation number judgment control unit
14B Pump well water level setting unit
14C Pump speed control unit
15 Control selector
16 Optimal control evaluation means
17 Process control unit
18 Manual operation means
19 Variable definition section
20 Variable definition section
21 Subtractor
WL1, WL2 Water level gauge
P1, P2, ..., PM Rainwater pump
V1, V2, ..., VM discharge valve
J1, J2, ..., JT Rainwater drainage control amount calculation unit
L Online signal line
O Applicable equipment

Claims (12)

A plurality of rainwater drainage control amount calculations including a prediction model that calculates a predicted amount of a predetermined target object based on input of process data, and a control model that calculates a control amount of a predetermined target device based on the predicted amount calculated by the prediction model. Department and
A control selection unit that evaluates each control performance with respect to the plurality of rainwater drainage control amount calculation units, and selects one of which obtains the optimum control performance based on the evaluation,
A process control unit that controls the predetermined target device based on a calculation result of the rainwater drainage control amount calculation unit selected by the control selection unit,
A rainwater drainage control device comprising: The control selection unit, the evaluation and the selection, when an abnormality occurs in the currently selected rainwater drainage control amount calculation unit, is to perform the other plurality of rainwater drainage control amount calculation unit,
The rainwater drainage control device according to claim 1, wherein: The control selection unit performs the evaluation and the selection at predetermined intervals.
The rainwater drainage control device according to claim 1 or 2, wherein: The prediction model is based on a white-box approach or a black-box approach, and calculates the prediction amount.
The rainwater drainage control device according to any one of claims 1 to 3, wherein: The parameters of the prediction model or control model of the rainwater drainage control amount calculation unit are to be updated online based on process data.
The rainwater drainage control device according to any one of claims 1 to 4, wherein: The rainwater drainage control amount calculation unit is configured to calculate an optimal control amount using at least one of an operation time, an operation cost, and an operation amount as an index.
The rainwater drainage control device according to any one of claims 1 to 5, wherein: The rainwater drainage control amount calculation unit calculates the optimum control amount using Receiving horizon control in which a constraint is applied to a predetermined control amount.
The rainwater drainage control device according to claim 6, wherein: The rainwater drainage control amount calculation unit calculates the optimal control amount using a branch and bound method,
The rainwater drainage control device according to claim 6, wherein: The rainwater drainage control amount calculation unit performs the calculation of the optimal control amount using a genetic algorithm,
The rainwater drainage control device according to claim 6, wherein: The rainwater drainage control amount calculation unit calculates the optimum control amount in consideration of rainfall information from a rainfall radar or a ground-based rain gauge,
The rainwater drainage control device according to claim 6, wherein: The rainwater drainage control amount calculation unit is for determining a control value for a discrete-time event based on a continuous-time event value, or determining a control value for a continuous-time event based on a discrete-time event value. By using auxiliary variables that relate between continuous-time and discrete-time events,
The rainwater drainage control device according to any one of claims 1 to 10, wherein: The control value related to the discrete time event based on the continuous time event value is the number of pumps operated based on the amount of rainwater inflow, and the control value related to the continuous time event based on the discrete time event value is the pump rotation number based on the pump operated number. Is a number,
The rainwater drainage control device according to claim 11, wherein:

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