CN110554655B - Intelligent hydraulic flood control gate and control system thereof - Google Patents
Intelligent hydraulic flood control gate and control system thereof Download PDFInfo
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- CN110554655B CN110554655B CN201910848503.7A CN201910848503A CN110554655B CN 110554655 B CN110554655 B CN 110554655B CN 201910848503 A CN201910848503 A CN 201910848503A CN 110554655 B CN110554655 B CN 110554655B
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- E—FIXED CONSTRUCTIONS
- E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
- E02B—HYDRAULIC ENGINEERING
- E02B7/00—Barrages or weirs; Layout, construction, methods of, or devices for, making same
- E02B7/20—Movable barrages; Lock or dry-dock gates
- E02B7/26—Vertical-lift gates
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- E—FIXED CONSTRUCTIONS
- E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
- E02B—HYDRAULIC ENGINEERING
- E02B7/00—Barrages or weirs; Layout, construction, methods of, or devices for, making same
- E02B7/20—Movable barrages; Lock or dry-dock gates
- E02B7/26—Vertical-lift gates
- E02B7/36—Elevating mechanisms for vertical-lift gates
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- G—PHYSICS
- G05—CONTROLLING; REGULATING
- G05B—CONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
- G05B19/00—Programme-control systems
- G05B19/02—Programme-control systems electric
- G05B19/04—Programme control other than numerical control, i.e. in sequence controllers or logic controllers
- G05B19/05—Programmable logic controllers, e.g. simulating logic interconnections of signals according to ladder diagrams or function charts
- G05B19/054—Input/output
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- G—PHYSICS
- G05—CONTROLLING; REGULATING
- G05B—CONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
- G05B2219/00—Program-control systems
- G05B2219/10—Plc systems
- G05B2219/11—Plc I-O input output
- G05B2219/1103—Special, intelligent I-O processor, also plc can only access via processor
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Abstract
The invention discloses an intelligent hydraulic flood gate and a control system thereof, which comprises a human-computer interface touch screen, an operation fault monitoring indicator light, an ultrasonic water level sensor, a radar current meter, a pull rope displacement sensor and an intermediate relay which are all connected with a PLC (programmable logic controller), wherein the intermediate relay is also connected with a hydraulic hoist, and the hydraulic hoist is connected with the flood gate. But also can process dangerous cases in time, so that the flood control work can be safely and effectively carried out.
Description
The technical field is as follows:
the invention belongs to the technical field of intelligent electromechanical control, and particularly relates to an intelligent hydraulic flood gate and a control system thereof.
Background art:
the traditional hydraulic hoist realizes the opening and closing of an oil cylinder by controlling a motor and an electromagnetic valve of a hydraulic system through a simple starting control cabinet, thereby driving a gate to be opened and closed. The flood control gate is away from the control room for a certain distance, and if the flood control gate is in a dangerous case of flood, the gate cannot be opened in time to drain the flood and drain the waterlogging, so that the damage and the dangerous case are immeasurable. The control room is opened the degree of opening that the floodgate can not judge the gate yet, all need artifical naked eye to go the scene and look over, frequent coming and going gate scene and well control room also do not benefit to in time to handle the dangerous situation, and the degree of opening of gate is mostly estimated and is judged by staff's experience, can not accurately judge according to upper reaches actual water level, also can not combine the actual water velocity of low reaches drainage flood to open the height and the state to the floodgate and in time adjust, monitoring data and fault information are unable acquisition in time more, even increase staff's intensity of labour, also can't effectively improve work efficiency, not only staff's burden has increased, and it is also untimely to handle the dangerous situation, can't make flood control work safe go on effectively.
The invention content is as follows:
in order to solve the above problems, the present invention provides a technical solution:
the utility model provides an intelligent hydraulic pressure flood control gate and control system thereof, includes man-machine interface touch-sensitive screen, operational failure monitoring pilot lamp, ultrasonic wave level sensor, radar current meter, stay cord displacement sensor and the auxiliary relay that all is connected with the PLC controller, and wherein, auxiliary relay still is connected with the hydraulic hoist machine, and the hydraulic hoist machine is connected its characterized in that with flood control gate:
the human-computer interface touch screen is used for displaying the running conditions of all parts (such as upstream water level, downstream flood discharge flow rate and flood control gate opening degree) and realizing the input of user operation;
the operation fault monitoring indicator lamps are used for displaying whether each fault monitoring point operates normally or not, and each fault monitoring point corresponds to one group of fault indicator lamps;
the ultrasonic water level sensor is arranged at a position which is convenient for monitoring the water level condition at the upstream, is used for monitoring the upstream water level condition in real time and sends monitoring data to the PLC in real time;
the radar current meter is arranged at a position where the downstream is convenient to monitor the water flow condition, is used for monitoring the water flow of the downstream flood discharge in real time, and sends monitoring data to the PLC in real time;
the pull rope displacement sensor is arranged between the flood control gate and a hydraulic oil cylinder in the hydraulic hoist to acquire the opening condition of the field gate, is used for monitoring the opening height of the flood control gate in real time and sends monitoring data to the PLC in real time;
the intermediate relay is positioned beside the hydraulic hoist and used for receiving information of the PLC controller and controlling the opening and closing of the hydraulic hoist and different opening degrees (namely the opening degree);
the hydraulic hoist is positioned beside the flood control gate and used for controlling the lifting and descending of the flood control gate and the lifting height of the flood control gate;
the flood control gate is positioned in the drainage channel in the dam, and the water level and the flow of the upstream and the downstream are adjusted through the lifting height, so that the flood control purposes of draining floodwater and draining stagnant water are achieved.
The PLC controller is used for outputting a control signal to an intermediate relay according to real-time monitoring data of the ultrasonic water level sensor, the radar current meter and the stay cord displacement sensor after internal operation processing, and then the opening degree of the hydraulic hoist controlled by the intermediate relay realizes the adjustment of the lifting height of the flood gate, and simultaneously, the monitoring data is displayed on a human-computer interface touch screen in real time, and whether each part of fault monitoring points normally operates or not is displayed through an operation fault monitoring indicator lamp.
The human-computer interface touch screen, the operation fault monitoring indicator lamp and the PLC are all located in a remote central control room, and remote real-time monitoring and intelligent control are facilitated.
Further, an intelligent hydraulic pressure flood gate control system, its characterized in that: ultrasonic wave level sensor, radar current meter and stay cord displacement sensor be connected with the PLC controller, under the stable prerequisite of guaranteeing the transmission, can adopt wired or wireless connected mode according to actual conditions.
Further, the intelligent hydraulic flood gate and the control system thereof are characterized in that a PLC controller is used as a core to control the normal operation of the whole system, and the control method or strategy is as follows:
s101, respectively monitoring the upstream water level condition and the downstream flood discharge water flow rate in real time by using an ultrasonic water level sensor and a radar current meter, and transmitting monitoring data to a PLC (programmable logic controller) of a remote central control room in real time;
s102, after receiving data of the ultrasonic water level sensor and the radar current meter, the PLC calls an internal preset control algorithm to perform analysis and operation, and then outputs a control signal to an intermediate relay;
s103, the intermediate relay controls the opening of the hydraulic hoist in real time according to the control information of the PLC to realize the real-time adjustment of the lifting height of the flood gate, and meanwhile, the stay cord displacement sensor transmits the monitoring data back to the PLC controller in real time to form a complete control feedback loop;
and S104, in the whole process, the steps S101 to S103 are carried out in a circulating mode all the time, meanwhile, the PLC displays monitoring data (such as upstream water level, downstream flood discharge flow rate and opening degree of a flood gate) on a human-computer interface touch screen in real time, and information about whether fault monitoring points of all parts operate normally is displayed through operating fault monitoring indicating lamps.
Further, the control algorithm preset in the PLC controller is characterized in that: according to the upstream actual monitoring water level h and the safe water level h0Will divide into hydraulic pressureThe opening degree of the hoist is divided into three safety levels, and then the water flow velocity v and the optimal water flow velocity v are monitored according to the actual downstream flood discharge0And (4) fine adjustment is carried out, and the specific safety level, the applicable condition, the control algorithm and the opening height and the state of the flood gate are shown in the following table.
Wherein:
h-upstream monitoring the actual water level;
h0the safe level of the station, i.e. the optimal level at which the upstream water level is below the safety warning line and the water storage capacity is reasonable;
h1-a water level of vigilance at a safety level of level 1, determined by the station on the basis of long-term observed practical conditions;
h2-a water level of vigilance at a safety level of level 2, determined by the station on the basis of long-term observed actual conditions;
k-opening value of the hydraulic hoist, called opening for short;
h-actual opening height of the flood gate;
H0-the maximum height of opening of the floodgate;
alpha-opening factor, actual monitored water flow rate v and optimal water flow rate v from downstream flood discharge0Determining;
the K' -opening correction value is related to local climatic conditions, including temperature, humidity, wind, sunshine time, rainfall and other related factors;
v-actual monitored water flow rate for downstream flood discharge;
v0-optimal water flow rate for downstream flood discharge, determined by the station based on long-term observed practices;
in addition, the safety level h of the station01-level warning water level h1And 2-level warning water level h2The relationship of (1) is: h is0<h1<h2;
The opening coefficient alpha is determined by the actual monitored water flow velocity v and the optimal water flow velocity v of the downstream flood discharge0DeterminingThe method specifically comprises the following steps:
(1) when v is less than or equal to v0When α is 1;
(2) when v is>v0When the temperature of the water is higher than the set temperature,wherein n is the adjustment stage number of the opening coefficient alpha, and is selected according to the amplitude and the rate of the water level change of the local station, and the value is generally 2.
The invention has the beneficial effects that: compared with the prior art, the invention can carry out hierarchical control on the flood control gate according to the actual upstream monitoring water level and the actual downstream flood discharge monitoring water flow rate, can intelligently adjust the opening height and the state of the flood control gate in real time, timely displays the monitoring data and the fault information, does not need to frequently go to the gate site and a central control room, effectively reduces the labor intensity of workers, improves the working efficiency of the system, realizes the purpose of intelligent remote control, not only greatly lightens the burden of the workers, but also can timely process dangerous situations, and ensures that the flood control work is safely and effectively carried out.
Description of the drawings:
for ease of illustration, the invention is described in detail by the following detailed description and the accompanying drawings.
FIG. 1 is a schematic diagram of a control system according to the present invention;
fig. 2 is a schematic diagram of the field layout of the present invention.
In the figure: the system comprises a human-computer interface touch screen, a 2-operation fault monitoring indicator lamp, a 3-PLC controller, a 4-central control room, a 5-ultrasonic water level sensor, a 6-intermediate relay, a 7-hydraulic hoist, an 8-flood gate, a 9-pull rope displacement sensor and a 10-radar current meter.
The specific implementation mode is as follows:
example 1
As shown in fig. 1-2, the following technical solutions are adopted in the present embodiment: the utility model provides an intelligent hydraulic pressure flood control gate and control system thereof, includes man-machine interface touch-sensitive screen, operational failure monitoring pilot lamp, ultrasonic wave level sensor, radar current meter, stay cord displacement sensor and the auxiliary relay that all is connected with the PLC controller, and wherein, auxiliary relay still is connected with the hydraulic hoist machine, and the hydraulic hoist machine is connected its characterized in that with flood control gate:
the human-computer interface touch screen is used for displaying the running conditions of all parts (such as upstream water level, downstream flood discharge flow rate and flood control gate opening degree) and realizing the input of user operation;
the operation fault monitoring indicator lamps are used for displaying whether each fault monitoring point operates normally or not, and each fault monitoring point corresponds to one group of fault indicator lamps;
the ultrasonic water level sensor is arranged at a position which is convenient for monitoring the water level condition at the upstream, is used for monitoring the upstream water level condition in real time and sends monitoring data to the PLC in real time;
the radar current meter is arranged at a position where the downstream is convenient to monitor the water flow condition, is used for monitoring the water flow of the downstream flood discharge in real time, and sends monitoring data to the PLC in real time;
the pull rope displacement sensor is arranged between the flood control gate and a hydraulic oil cylinder in the hydraulic hoist to acquire the opening condition of the field gate, is used for monitoring the opening height of the flood control gate in real time and sends monitoring data to the PLC in real time;
the intermediate relay is positioned beside the hydraulic hoist and used for receiving information of the PLC controller and controlling the opening and closing of the hydraulic hoist and different opening degrees (namely the opening degree);
the hydraulic hoist is positioned beside the flood control gate and used for controlling the lifting and descending of the flood control gate and the lifting height of the flood control gate;
the flood control gate is positioned in the drainage channel in the dam, and the water level and the flow of the upstream and the downstream are adjusted through the lifting height, so that the flood control purposes of draining floodwater and draining stagnant water are achieved.
The PLC controller is used for outputting a control signal to an intermediate relay according to real-time monitoring data of the ultrasonic water level sensor, the radar current meter and the stay cord displacement sensor after internal operation processing, and then the opening degree of the hydraulic hoist controlled by the intermediate relay realizes the adjustment of the lifting height of the flood gate, and simultaneously, the monitoring data is displayed on a human-computer interface touch screen in real time, and whether each part of fault monitoring points normally operates or not is displayed through an operation fault monitoring indicator lamp.
The human-computer interface touch screen, the operation fault monitoring indicator lamp and the PLC are all located in a remote central control room, and remote real-time monitoring and intelligent control are facilitated.
Specifically, intelligent hydraulic pressure flood gate control system, its characterized in that: ultrasonic wave level sensor, radar current meter and stay cord displacement sensor be connected with the PLC controller, under the stable prerequisite of guaranteeing the transmission, can adopt wired or wireless connected mode according to actual conditions.
The key components of the invention can be selected to meet the actual use requirements, and the specific selection can refer to the following table:
example 2
As shown in fig. 1-2, the following technical solutions are adopted in the present embodiment: the utility model provides an intelligent hydraulic pressure flood control gate and control system thereof, includes man-machine interface touch-sensitive screen, operational failure monitoring pilot lamp, ultrasonic wave level sensor, radar current meter, stay cord displacement sensor and the auxiliary relay that all is connected with the PLC controller, and wherein, auxiliary relay still is connected with the hydraulic hoist machine, and the hydraulic hoist machine is connected its characterized in that with flood control gate:
the human-computer interface touch screen is used for displaying the running conditions of all parts (such as upstream water level, downstream flood discharge flow rate and flood control gate opening degree) and realizing the input of user operation;
the operation fault monitoring indicator lamps are used for displaying whether each fault monitoring point operates normally or not, and each fault monitoring point corresponds to one group of fault indicator lamps;
the ultrasonic water level sensor is arranged at a position which is convenient for monitoring the water level condition at the upstream, is used for monitoring the upstream water level condition in real time and sends monitoring data to the PLC in real time;
the radar current meter is arranged at a position where the downstream is convenient to monitor the water flow condition, is used for monitoring the water flow of the downstream flood discharge in real time, and sends monitoring data to the PLC in real time;
the pull rope displacement sensor is arranged between the flood control gate and a hydraulic oil cylinder in the hydraulic hoist to acquire the opening condition of the field gate, is used for monitoring the opening height of the flood control gate in real time and sends monitoring data to the PLC in real time;
the intermediate relay is positioned beside the hydraulic hoist and used for receiving information of the PLC controller and controlling the opening and closing of the hydraulic hoist and different opening degrees (namely the opening degree);
the hydraulic hoist is positioned beside the flood control gate and used for controlling the lifting and descending of the flood control gate and the lifting height of the flood control gate;
the flood control gate is positioned in the drainage channel in the dam, and the water level and the flow of the upstream and the downstream are adjusted through the lifting height, so that the flood control purposes of draining floodwater and draining stagnant water are achieved.
The PLC controller is used for outputting a control signal to an intermediate relay according to real-time monitoring data of the ultrasonic water level sensor, the radar current meter and the stay cord displacement sensor after internal operation processing, and then the opening degree of the hydraulic hoist controlled by the intermediate relay realizes the adjustment of the lifting height of the flood gate, and simultaneously, the monitoring data is displayed on a human-computer interface touch screen in real time, and whether each part of fault monitoring points normally operates or not is displayed through an operation fault monitoring indicator lamp.
The human-computer interface touch screen, the operation fault monitoring indicator lamp and the PLC are all located in a remote central control room, and remote real-time monitoring and intelligent control are facilitated.
Specifically, intelligent hydraulic pressure flood gate control system, its characterized in that: ultrasonic wave level sensor, radar current meter and stay cord displacement sensor be connected with the PLC controller, under the stable prerequisite of guaranteeing the transmission, can adopt wired or wireless connected mode according to actual conditions.
Specifically, the intelligent hydraulic flood gate and the control system thereof are characterized in that a PLC controller is used as a core to control the normal operation of the whole system, and the control method or strategy is as follows:
s101, respectively monitoring the upstream water level condition and the downstream flood discharge water flow rate in real time by using an ultrasonic water level sensor and a radar current meter, and transmitting monitoring data to a PLC (programmable logic controller) of a remote central control room in real time;
s102, after receiving data of the ultrasonic water level sensor and the radar current meter, the PLC calls an internal preset control algorithm to perform analysis and operation, and then outputs a control signal to an intermediate relay;
s103, the intermediate relay controls the opening of the hydraulic hoist in real time according to the control information of the PLC to realize the real-time adjustment of the lifting height of the flood gate, and meanwhile, the stay cord displacement sensor transmits the monitoring data back to the PLC controller in real time to form a complete control feedback loop;
and S104, in the whole process, the steps S101 to S103 are carried out in a circulating mode all the time, meanwhile, the PLC displays monitoring data (such as upstream water level, downstream flood discharge flow rate and opening degree of a flood gate) on a human-computer interface touch screen in real time, and information about whether fault monitoring points of all parts operate normally is displayed through operating fault monitoring indicating lamps.
Specifically, the control algorithm preset in the PLC controller is characterized in that: according to the upstream actual monitoring water level h and the safe water level h0The opening degree of the hydraulic split hoist is divided into three safety levels, and the specific safety level, the application condition, the control algorithm and the opening height and the state of the flood gate are shown in the following table.
Wherein:
h-upstream monitoring the actual water level;
h0the safe level of the station, i.e. the optimal level at which the upstream water level is below the safety warning line and the water storage capacity is reasonable;
h1-a water level of vigilance at a safety level of level 1, determined by the station on the basis of long-term observed practical conditions;
h2a water level of vigilance at a security level of level 2, by the station rootDetermining according to the actual situation of long-term observation;
k-opening value of the hydraulic hoist, called opening for short;
h-actual opening height of the flood gate;
H0-the maximum height of opening of the floodgate;
the K' -opening correction value is related to local climatic conditions, including temperature, humidity, wind, sunshine duration, rainfall and other related factors.
In addition, the safety level h of the station01-level warning water level h1And 2-level warning water level h2The relationship of (1) is: h is0<h1<h2。
The key components of the invention can be selected to meet the actual use requirements, and the specific selection can refer to the following table:
example 3
As shown in fig. 1-2, the following technical solutions are adopted in the present embodiment: the utility model provides an intelligent hydraulic pressure flood control gate and control system thereof, includes man-machine interface touch-sensitive screen, operational failure monitoring pilot lamp, ultrasonic wave level sensor, radar current meter, stay cord displacement sensor and the auxiliary relay that all is connected with the PLC controller, and wherein, auxiliary relay still is connected with the hydraulic hoist machine, and the hydraulic hoist machine is connected its characterized in that with flood control gate:
the human-computer interface touch screen is used for displaying the running conditions of all parts (such as upstream water level, downstream flood discharge flow rate and flood control gate opening degree) and realizing the input of user operation;
the operation fault monitoring indicator lamps are used for displaying whether each fault monitoring point operates normally or not, and each fault monitoring point corresponds to one group of fault indicator lamps;
the ultrasonic water level sensor is arranged at a position which is convenient for monitoring the water level condition at the upstream, is used for monitoring the upstream water level condition in real time and sends monitoring data to the PLC in real time;
the radar current meter is arranged at a position where the downstream is convenient to monitor the water flow condition, is used for monitoring the water flow of the downstream flood discharge in real time, and sends monitoring data to the PLC in real time;
the pull rope displacement sensor is arranged between the flood control gate and a hydraulic oil cylinder in the hydraulic hoist to acquire the opening condition of the field gate, is used for monitoring the opening height of the flood control gate in real time and sends monitoring data to the PLC in real time;
the intermediate relay is positioned beside the hydraulic hoist and used for receiving information of the PLC controller and controlling the opening and closing of the hydraulic hoist and different opening degrees (namely the opening degree);
the hydraulic hoist is positioned beside the flood control gate and used for controlling the lifting and descending of the flood control gate and the lifting height of the flood control gate;
the flood control gate is positioned in the drainage channel in the dam, and the water level and the flow of the upstream and the downstream are adjusted through the lifting height, so that the flood control purposes of draining floodwater and draining stagnant water are achieved.
The PLC controller is used for outputting a control signal to an intermediate relay according to real-time monitoring data of the ultrasonic water level sensor, the radar current meter and the stay cord displacement sensor after internal operation processing, and then the opening degree of the hydraulic hoist controlled by the intermediate relay realizes the adjustment of the lifting height of the flood gate, and simultaneously, the monitoring data is displayed on a human-computer interface touch screen in real time, and whether each part of fault monitoring points normally operates or not is displayed through an operation fault monitoring indicator lamp.
The human-computer interface touch screen, the operation fault monitoring indicator lamp and the PLC are all located in a remote central control room, and remote real-time monitoring and intelligent control are facilitated.
Specifically, intelligent hydraulic pressure flood gate control system, its characterized in that: ultrasonic wave level sensor, radar current meter and stay cord displacement sensor be connected with the PLC controller, under the stable prerequisite of guaranteeing the transmission, can adopt wired or wireless connected mode according to actual conditions.
Specifically, the intelligent hydraulic flood gate and the control system thereof are characterized in that a PLC controller is used as a core to control the normal operation of the whole system, and the control method or strategy is as follows:
s101, respectively monitoring the upstream water level condition and the downstream flood discharge water flow rate in real time by using an ultrasonic water level sensor and a radar current meter, and transmitting monitoring data to a PLC (programmable logic controller) of a remote central control room in real time;
s102, after receiving data of the ultrasonic water level sensor and the radar current meter, the PLC calls an internal preset control algorithm to perform analysis and operation, and then outputs a control signal to an intermediate relay;
s103, the intermediate relay controls the opening of the hydraulic hoist in real time according to the control information of the PLC to realize the real-time adjustment of the lifting height of the flood gate, and meanwhile, the stay cord displacement sensor transmits the monitoring data back to the PLC controller in real time to form a complete control feedback loop;
and S104, in the whole process, the steps S101 to S103 are carried out in a circulating mode all the time, meanwhile, the PLC displays monitoring data (such as upstream water level, downstream flood discharge flow rate and opening degree of a flood gate) on a human-computer interface touch screen in real time, and information about whether fault monitoring points of all parts operate normally is displayed through operating fault monitoring indicating lamps.
Specifically, the control algorithm preset in the PLC controller is characterized in that: according to the upstream actual monitoring water level h and the safe water level h0Dividing the opening of the hydraulic opening and closing machine into three safety levels, and then according to the actual monitoring water flow velocity v and the optimal water flow velocity v of the downstream flood discharge0And (4) fine adjustment is carried out, and the specific safety level, the applicable condition, the control algorithm and the opening height and the state of the flood gate are shown in the following table.
Wherein:
h-upstream monitoring the actual water level;
h0the safe level of the station, i.e. the optimal level at which the upstream water level is below the safety warning line and the water storage capacity is reasonable;
h1-a water level of vigilance at a safety level of level 1, determined by the station on the basis of long-term observed practical conditions;
h2-a water level of vigilance at a safety level of level 2, determined by the station on the basis of long-term observed actual conditions;
k-opening value of the hydraulic hoist, called opening for short;
h-actual opening height of the flood gate;
H0-the maximum height of opening of the floodgate;
alpha-opening factor, actual monitored water flow rate v and optimal water flow rate v from downstream flood discharge0Determining;
the K' -opening correction value is related to local climatic conditions, including temperature, humidity, wind, sunshine time, rainfall and other related factors;
v-actual monitored water flow rate for downstream flood discharge;
v0-optimal water flow rate for downstream flood discharge, determined by the station based on long-term observed practices;
in addition, the safety level h of the station01-level warning water level h1And 2-level warning water level h2The relationship of (1) is: h is0<h1<h2;
The opening coefficient alpha is determined by the actual monitored water flow velocity v and the optimal water flow velocity v of the downstream flood discharge0Determining, specifically:
(1) when v is less than or equal to v0When α is 1;
(2) when v is>v0When the temperature of the water is higher than the set temperature,wherein n is the adjustment stage number of the opening coefficient alpha, and is selected according to the amplitude and the rate of the water level change of the local station, and the value is generally 2.
The key components of the invention can be selected to meet the actual use requirements, and the specific selection can refer to the following table:
the invention has the beneficial effects that: compared with the prior art, the invention can carry out hierarchical control on the flood control gate according to the actual upstream monitoring water level and the actual downstream flood discharge monitoring water flow rate, can intelligently adjust the opening height and the state of the flood control gate in real time, timely displays the monitoring data and the fault information, does not need to frequently go to the gate site and a central control room, effectively reduces the labor intensity of workers, improves the working efficiency of the system, realizes the purpose of intelligent remote control, not only greatly lightens the burden of the workers, but also can timely process dangerous situations, and ensures that the flood control work is safely and effectively carried out.
While there have been shown and described what are at present considered to be the fundamental principles of the invention and its essential features and advantages, it will be understood by those skilled in the art that the invention is not limited by the embodiments described above, which are merely illustrative of the principles of the invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the invention as defined by the appended claims and their equivalents.
Claims (3)
1. The utility model provides an intelligent hydraulic pressure flood gate and control system thereof which characterized in that: the device comprises a human-computer interface touch screen, an operation fault monitoring indicator lamp, an ultrasonic water level sensor, a radar flow meter, a pull rope displacement sensor and an intermediate relay which are all connected with a PLC (programmable logic controller), wherein the intermediate relay is also connected with a hydraulic hoist;
the human-computer interface touch screen is used for displaying the running conditions of all parts, including the conditions of upstream water level, downstream flood discharge flow rate and flood control gate opening, and realizing the input of user operation;
the operation fault monitoring indicator lamps are used for displaying whether fault monitoring points of each part operate normally or not, and each fault monitoring point corresponds to one group of fault indicator lamps;
the ultrasonic water level sensor is arranged at a position convenient for monitoring the water level condition at the upstream, and is used for monitoring the upstream water level condition in real time and sending the monitoring data to the PLC in real time;
the radar current meter is arranged at a position where the downstream can conveniently monitor the water flow speed condition, is used for monitoring the water flow speed of the downstream flood discharge in real time, and sends monitoring data to the PLC in real time;
the pull rope displacement sensor is arranged between the flood control gate and a hydraulic oil cylinder in the hydraulic hoist to acquire the opening condition of the field gate, is used for monitoring the opening height of the flood control gate in real time and sends monitoring data to the PLC in real time;
the intermediate relay is positioned beside the hydraulic hoist and used for receiving information of the PLC controller and controlling the opening and closing of the hydraulic hoist and different opening degrees;
the hydraulic hoist is positioned beside the flood control gate and used for controlling the lifting and descending of the flood control gate and the lifting height of the flood control gate;
the flood control gate is positioned in the drainage channel in the dam, and the water level and flow of the upstream and downstream are adjusted through the lifting height, so that the flood control purposes of draining floodwater and draining stagnant water are achieved;
the PLC is used for outputting a control signal to the intermediate relay after being operated and processed by an internal preset control algorithm according to real-time monitoring data of the ultrasonic water level sensor, the radar current meter and the pull rope displacement sensor, further controlling the opening of the hydraulic hoist by the intermediate relay to realize the adjustment of the lifting height of the flood gate, simultaneously displaying the monitoring data on a human-computer interface touch screen in real time, and displaying information whether fault monitoring points of all parts are normal in operation or not through an operation fault monitoring indicator lamp;
the human-computer interface touch screen, the operation fault monitoring indicator lamp and the PLC are all positioned in a remote central control room, so that remote real-time monitoring and intelligent control are facilitated;
a control algorithm preset in the PLC controller is used for monitoring the water level h and the safe water level h according to the upstream practical monitoring water level h0Dividing the opening of the hydraulic opening and closing machine into three safety levels, and then according to the actual monitoring water flow velocity v and the optimal water flow velocity v of the downstream flood discharge0Fine adjustment is carried out, and specific safety level, applicable condition and control algorithm are carried outAnd the opening height and the state of the flood gate are as follows:
(1) mode with security level 0
The applicable conditions are as follows: h-h0∈(-∞,h1)
And (3) a control algorithm: k is 0
In the mode, the opening height H of the flood gate is 0, and the flood gate is in a fully closed state;
(2) mode with security level 1
The applicable conditions are as follows: h-h0∈(h1,h2)
in this mode, the opening height H of the flood gate is K.H0Is a dynamic adjustment state;
(3) mode with security level 2
The applicable conditions are as follows: h-h0∈(h2,+∞)
And (3) a control algorithm: k is 1
In this mode, the opening height H of the flood gate is equal to H0Is in a full open state;
wherein: h-upstream monitoring the actual water level;
h0the safe level of the station, i.e. the optimal level at which the upstream water level is below the safety warning line and the water storage capacity is reasonable;
h1-a water level of vigilance at a safety level of level 1, determined by the station on the basis of long-term observed practical conditions;
h2-a water level of vigilance at a safety level of level 2, determined by the station on the basis of long-term observed actual conditions;
k-opening value of the hydraulic hoist, called opening for short;
h-actual opening height of the flood gate;
H0-the maximum height of opening of the floodgate;
alpha-opening factor, actual monitored water flow rate v and optimal water flow rate v from downstream flood discharge0Determining;
the K' -opening correction value is related to local climatic conditions, including air temperature, humidity, wind speed, sunshine time and rainfall;
v-actual monitored water flow rate for downstream flood discharge;
v0-optimal water flow rate for downstream flood discharge, determined by the station based on long-term observed practices;
in addition, the opening coefficient alpha is obtained by the actual monitored water flow velocity v and the optimal water flow velocity v of the downstream flood discharge0Determining, specifically:
(1) when v is less than or equal to v0When α is 1;
2. An intelligent hydraulic floodgate and a control system thereof according to claim 1, wherein: ultrasonic wave level sensor, radar current meter and stay cord displacement sensor be connected with the PLC controller, under the stable prerequisite of guaranteeing the transmission, can adopt wired or wireless connected mode according to actual conditions.
3. The intelligent hydraulic floodgate and the control system thereof according to claim 1, wherein the normal operation of the whole system is controlled by taking a PLC as a core, and the control flow is as follows:
s101, respectively monitoring the upstream water level condition and the downstream flood discharge water flow rate in real time by using an ultrasonic water level sensor and a radar flow rate meter, and transmitting monitoring data to a PLC (programmable logic controller) of a remote central control room in real time;
s102, after receiving data of the ultrasonic water level sensor and the radar current meter, the PLC calls an internal preset control algorithm to perform analysis and operation, and then outputs a control signal to an intermediate relay;
s103, the intermediate relay controls the opening of the hydraulic hoist in real time according to the control information of the PLC to realize the real-time adjustment of the lifting height of the flood gate, and meanwhile, the stay cord displacement sensor transmits the monitoring data back to the PLC controller in real time to form a complete control feedback loop;
and S104, in the whole process, the steps S101-S103 are carried out in a circulating mode all the time, meanwhile, the PLC displays the monitoring data on the human-computer interface touch screen in real time, and information about whether the fault monitoring points of each part operate normally is displayed through the operation fault monitoring indicator lamp.
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