CN111140473B - Diaphragm pump remote control system - Google Patents

Abstract

The invention discloses a diaphragm pump remote control system, which belongs to the technical field of pump control systems and comprises a plurality of electromagnetic valves for controlling the diaphragm pump to work, a control end arranged on mobile equipment and a plurality of controlled ends arranged on the electromagnetic valves; the control end comprises a control wireless module, a state display module and an independent control module; the controlled end comprises a controlled wireless module, a start-stop control module and a state feedback module, the control end sends a signal to the controlled end to control the opening and closing of the electromagnetic valve, and the controlled end sends the current state of the electromagnetic valve back to the control end to be displayed.

Description

Diaphragm pump remote control system

Technical Field

The invention relates to the technical field of pump control systems, in particular to a remote control system of a diaphragm pump.

Background

Diaphragm pumps, also known as control pumps, are currently the main type of actuator that is operated by power to vary the fluid flow by receiving a control signal from a regulating control unit. The diaphragm pump is used in the control process to receive the control signal of the regulator or the computer and change the flow rate of the regulated medium to maintain the regulated parameters in the required range, so as to realize the automation of the production process. If the automatic adjustment system is compared to a manual adjustment process, the detection unit is the human eye and the adjustment control unit is the human brain, the execution units, the membrane pumps, are the human hand and foot. The diaphragm pump is not required to be opened to realize the adjustment and control of certain parameters of the process, such as temperature, pressure, flow, liquid level and the like.

In the prior art, the patent of the invention of chinese patent application publication No. CN108457848A is referred to and discloses a magnetic induction precise control diaphragm pump and a diaphragm pump control device, wherein the magnetic induction precise control diaphragm pump comprises a motor base, a diaphragm pump head, a motor, a magnetic part and a coil, and the motor base is provided with an accommodating cavity; the diaphragm pump head is arranged at the top of the motor base and seals the accommodating cavity; the motor is fixed at the bottom of the motor base, and a driving shaft of the motor is accommodated in the accommodating cavity, extends along the vertical direction and is connected with the diaphragm pump head; the magnetic part is arranged in the accommodating cavity and can rotate around the axis of the driving shaft along with the rotation of the driving shaft; the coil is arranged in the accommodating cavity, and when the magnetic part rotates relative to the coil, the coil generates an induced current signal.

The above prior art solutions have the following drawbacks: when using a plurality of diaphragm pumps simultaneously, when the user is not beside the diaphragm pump, the user can't control the diaphragm pump, can consume the manpower among the industrial market process.

Disclosure of Invention

The invention aims to provide a remote control system for diaphragm pumps, which can remotely and wirelessly control any number of diaphragm pumps without manual operation of personnel.

The technical purpose of the invention is realized by the following technical scheme:

a diaphragm pump remote control system comprises a plurality of electromagnetic valves for controlling a diaphragm pump to work, a control end arranged on mobile equipment and a plurality of controlled ends arranged on the electromagnetic valves;

the control end comprises a control wireless module, a state display module and an independent control module;

the control wireless module is used for receiving and sending wireless signals;

the state display module is used for displaying the on-off state of each diaphragm pump;

the independent control module stores the number of each controlled end, receives an external instruction and transmits the number and a starting signal or a stopping signal to the control wireless module, and the control wireless module sends the received starting signal or stopping signal to the controlled end with the corresponding number;

the controlled end comprises a controlled wireless module, a start-stop control module and a state feedback module;

the controlled wireless module stores a serial number, receives a starting signal or a stopping signal sent by the control wireless module and transmits the starting signal or the stopping signal to the start-stop control module;

the start-stop control module receives the start signal and then controls the corresponding electromagnetic valve to be powered on and opened, and the start-stop control module receives the stop signal and then controls the corresponding electromagnetic valve to be powered off and closed;

the state feedback module detects the opening and closing state of the electromagnetic valve, when the opening and closing state of the electromagnetic valve changes, the state feedback module sends a current state signal to the controlled wireless module according to the current state of the electromagnetic valve, the controlled wireless module sends the current state signal to the control wireless module, the control wireless module transmits the current state signal to the state display module, and the state display module adjusts the displayed opening and closing state according to the current state signal.

By adopting the above scheme, the user sends a signal to the controlled end through the control end to control the opening and closing of the electromagnetic valve, the controlled end sends the current state of the electromagnetic valve back to the control end to display the user, remote wireless control can be carried out on any number of diaphragm pumps, manual operation of personnel is not needed, each diaphragm pump has a corresponding number, user identification is convenient, and the working condition of each diaphragm pump can be fed back like the user, so that the user can control the working condition of each diaphragm pump according to the actual condition.

The invention is further configured to: the electromagnetic valve power supply system also comprises a main power supply circuit connected with all the electromagnetic valves and a main control end connected with the main power supply circuit, wherein the main power supply circuit controls the power supplies of all the electromagnetic valves;

the control end also comprises a master control module, the master control module receives an external instruction and transmits a master start signal or a master stop signal to the control wireless module, and the control wireless module sends the received transmission master start signal or the received transmission master stop signal to the master control end;

the master control end comprises a master control wireless module and a power supply control module;

the master control wireless module receives a master start signal or a master stop signal sent by the control wireless module and transmits the master start signal or the master stop signal to the power supply control module;

and the power supply control module controls the on-off of a total power supply circuit according to the received total starting signal or total stopping signal.

By adopting the scheme, a user can send a signal to the master control end through the control end to simultaneously control the starting and stopping of all the diaphragm pumps.

The invention is further configured to: the state feedback module comprises a flowmeter arranged at a liquid outlet of the diaphragm pump, the flowmeter is used for detecting a flow value, the state feedback module sends the flow value and a stored serial number to the controlled wireless module, the controlled wireless module sends the flow value to the control wireless module, the control wireless module transmits the flow value and the serial number to the state display module, and the state display module displays the flow value at a corresponding position according to the serial number.

By adopting the scheme, the control end can display the flow value of the liquid outlet of each diaphragm pump for a user, so that the user can know the running state of the whole system in real time.

The invention is further configured to: the control end still touches the affirmation module including the mistake, the mistake touches the affirmation module and receives the start signal or stop signal of independent control module output and total start signal or total stop signal of total control module output, intercepts this signal and shows the reconfirmation window after the mistake touches the affirmation module and receives arbitrary signal, touches the affirmation module when the mistake and receives the affirmation signal that comes from the reconfirmation window after, stops intercepting.

By adopting the scheme, the control end firstly pops up the user and then confirms the window when the user tries to change the working state of the single diaphragm pump, and sends out the control signal after receiving the confirmation signal, so that the possibility that the diaphragm pump is accidentally controlled due to the fact that the user mistakenly touches the control end is reduced.

The invention is further configured to: the control end also comprises an accident judgment module and an accident alarm module;

the accident judgment module detects the flow value displayed by the state display module in real time, calculates the variation of the flow value in the set time, compares the variation with a preset value, and transmits an alarm signal to the accident alarm module when the variation is larger than the preset value;

and the accidental alarm module receives the alarm signal and then alarms by ringing.

By adopting the scheme, the control end can judge the working condition of each diaphragm pump through the flow value in real time, and can send an alarm to remind a user when the diaphragm pump works abnormally.

The invention is further configured to: the control end further comprises an accident processing module, the accident processing module receives a starting signal or a stopping signal output by the independent control module, when the accident processing module receives the starting signal or the stopping signal, the accident processing module calls an alarm signal output by the accident judgment module, when the accident processing module monitors the state of the accident alarm module, the accident alarm module rings to alarm and alarms for more than a set time, and the accident processing module controls the wireless module to send a signal opposite to the last sent signal.

By adopting the scheme, if the diaphragm pump judged by the control end works abnormally, the control end sends out an alarm and waits after sending a control signal through the control end, and if the user does not respond, the user can automatically remove the first step of operation to reduce loss.

The invention is further configured to: the mistaken touch confirmation module stores various curve graphs, randomly calls one curve graph when the mistaken touch confirmation module displays the re-confirmation window, and confirms the receiving confirmation signal by the re-confirmation window when the external inputs the information which is the same as the called curve graph.

By adopting the scheme, the reconfirmation window is composed of a random curve graph, and the interception can be removed only after the user draws the same curve, so that the possibility that the reconfirmation window is closed accidentally due to mistaken touch of the client is avoided.

The invention is further configured to: the control system also comprises a report generation module and a report storage module;

the flow value corresponding to the on-off state of each diaphragm pump displayed by the state display module is acquired by the report generation module in real time, a blank report is generated by the report generation module, the on-off state is made into a dot diagram by the report generation module and is filled into the blank report, the flow value is made into a curve diagram by the report generation module and is filled into the blank report, and the filled blank report is made into a unit time state report by the report generation module after set time, and the unit time state report is transmitted to the report storage module;

and the report storage module receives and stores the unit time state report.

By adopting the scheme, the control end can generate a unit time state report every time, so that a user can conveniently check the running condition of the historical diaphragm pump.

The invention is further configured to: the control end further comprises a pipeline diagram drawing module, the pipeline diagram drawing module is stored with a pipeline diagram base plate, the pipeline diagram drawing module receives external input information and generates diaphragm pump icons on the pipeline diagram base plate according to the received information, the pipeline diagram drawing module moves the diaphragm pump icons and draws pipeline lines according to the received information, finally a pipeline diagram is generated, the pipeline diagram drawing module transmits the pipeline diagram to the state display module, and the state display module displays all information on the pipeline diagram.

By adopting the scheme, the control end can enable a user to draw a pipeline diagram by oneself, so that the user can clearly and intuitively know the position of each diaphragm pump, and the possibility of control errors of the user is reduced.

The invention is further configured to: the control end also comprises an interface module which is externally connected with a storage device and stores or derives information to the report storage module.

By adopting the scheme, the user can upload or download the report form through the interface module.

In conclusion, the invention has the following beneficial effects:

1. the user sends a signal to the controlled end through the control end to control the opening and closing of the electromagnetic valve, the controlled end sends the current state of the electromagnetic valve back to the control end to display the user, remote wireless control can be performed on any number of diaphragm pumps, manual operation of personnel is not needed, each diaphragm pump has a corresponding number, user identification is convenient, the working condition of each diaphragm pump can be fed back like the user, and the user can control the working condition of each diaphragm pump according to the actual condition.

Drawings

FIG. 1 is an overall system block diagram of an embodiment;

FIG. 2 is a system block diagram highlighting a control end, a controlled end and a master control end in the embodiment;

FIG. 3 is a block diagram of a highlighted contingency determination module, a contingency alarm module and a contingency handling module in an embodiment;

FIG. 4 is a block diagram of a highlighted report generation module, a report storage module, and an interface module in an embodiment.

In the figure, 1, a control end; 11. a master control module; 12. an individual control module; 13. controlling the wireless module; 131. a false touch confirmation module; 14. a pipeline diagram drawing module; 15. a status display module; 16. an accident judgment module; 161. an accident warning module; 17. an accident handling module; 18. a report generation module; 181. a report storage module; 19. an interface module; 2. a controlled end; 21. a controlled wireless module; 22. a state feedback module; 221. a flow meter; 23. a start-stop control module; 24. an electromagnetic valve; 3. a master control end; 31. a master control wireless module; 32. a power supply control module; 33. a main power supply circuit.

Detailed Description

Example (b): a diaphragm pump remote control system is shown in figures 1 and 2 and comprises a plurality of electromagnetic valves 24 for controlling the diaphragm pump to work, a master power circuit 33 connected with all the electromagnetic valves 24, a control end 1 arranged on a mobile device, a plurality of controlled ends 2 arranged on the electromagnetic valves 24 and a master control end 3 connected with the master power circuit 33. The control end 1 comprises a total control module 11, an individual control module 12, a false touch confirmation module 131, a pipeline diagram drawing module 14 and a state display module 15. The controlled end 2 comprises a controlled wireless module 21, a start-stop control module 23 and a state feedback module 22. The master control end 3 comprises a master control wireless module 31 and a power control module 32.

As shown in fig. 2, the control radio module 13 is used for receiving and transmitting radio signals. The individual control module 12 stores the number of each controlled terminal 2, and the individual control module 12 receives an external instruction and transmits the number and a start signal or a stop signal to the control wireless module 13. The control wireless module 13 sends the received start signal or stop signal to the controlled end 2 with the corresponding number. The master control module 11 receives an external instruction and transmits a total start signal or a total stop signal to the control wireless module 13, and the control wireless module 13 sends the received transmission total start signal or the received transmission total stop signal to the master control terminal 3.

As shown in fig. 2, the controlled wireless module 21 stores a serial number, and the controlled wireless module 21 receives the start signal or the stop signal sent by the control wireless module 13 and transmits the start signal or the stop signal to the start-stop control module 23. The start-stop control module 23 receives the start signal and then controls the corresponding electromagnetic valve 24 to be powered on and opened, and the start-stop control module 23 receives the stop signal and then controls the corresponding electromagnetic valve 24 to be powered off and closed. A user can send a signal to the sub-control end through the control end 1 to control the starting and stopping of the single diaphragm pump.

As shown in fig. 2, the master control wireless module 31 receives the master start signal or the master stop signal sent by the control wireless module 13, and transmits the master start signal or the master stop signal to the power control module 32. The power control module 32 controls the overall power circuit 33 to be turned on or off according to the received overall start signal or overall stop signal. A user can send a signal to the master control end 3 through the control end 1 to control the start and stop of all the diaphragm pumps simultaneously.

As shown in fig. 2, the false touch confirmation module 131 receives the start signal or the stop signal output by the individual control module 12 and the total start signal or the total stop signal output by the total control module 11. When the false touch confirmation module 131 receives any signal, the signal is intercepted and a reconfirmation window is displayed. When the false touch confirmation module 131 receives a confirmation signal from the reconfirmation window, interception is stopped. The mis-touch confirmation module 131 stores a variety of curve patterns, randomly calls one curve pattern when the mis-touch confirmation module 131 displays a re-confirmation window, and confirms a reception confirmation signal by the re-confirmation window when information identical to the called curve pattern is input from the outside. When a user tries to change the working state of a single diaphragm pump, the control end 1 pops up a window to the user firstly and then confirms the window, and sends a control signal after receiving the confirmation signal, so that the possibility that the diaphragm pump is controlled accidentally due to the fact that the user touches the control end 1 by mistake is reduced. The reconfirmation window is composed of a random curve graph, interception can be removed only after a user draws the same curve, and the possibility that the reconfirmation window is closed accidentally due to mistaken touch is avoided.

As shown in fig. 2, the state feedback module 22 includes a flow meter 221 disposed at the liquid outlet of the diaphragm pump, and the flow meter 221 is used for detecting a flow value. The state feedback module 22 detects an open/close state of the electromagnetic valve 24, and when the open/close state of the electromagnetic valve 24 changes, the state feedback module 22 sends a current state signal to the controlled wireless module 21 according to the current state of the electromagnetic valve 24. The controlled wireless module 21 transmits the current status signal to the control wireless module 13, and the control wireless module 13 transmits the current status signal to the status display module 15. The state display module 15 adjusts the displayed on-off state according to the current state signal. The state feedback module 22 sends the flow value and the stored number to the controlled wireless module 21, and the controlled wireless module 21 sends the flow value to the control wireless module 13. The control radio module 13 transmits the flow value and the number to the status display module 15. And the state display module 15 displays the flow value at the corresponding position according to the number. Control end 1 can show the flow value that the open and close state and the liquid outlet of every diaphragm pump go out to the user, and the user of being convenient for knows entire system's running state in real time.

As shown in fig. 2, the pipeline drawing module 14 stores a pipeline drawing base, and the pipeline drawing module 14 receives information input from the outside and generates a diaphragm pump icon on the pipeline drawing base according to the received information. The piping diagram drawing module 14 moves the diaphragm pump icon and draws the piping line according to the received information, and finally generates a piping diagram. The pipeline map drawing module 14 transmits the pipeline map to the status display module 15, and the status display module 15 displays all information on the pipeline map. The control end 1 can enable a user to draw a pipeline diagram by himself, so that the user can know the position of each diaphragm pump clearly and intuitively, and the possibility of control errors of the user is reduced.

As shown in fig. 3, the control terminal 1 further includes an accident judgment module 16, an accident alarm module 161, and an accident handling module 17. The accident judgment module 16 detects the flow value displayed by the state display module 15 in real time, calculates the variation of the flow value within a set time, and compares the variation with a preset value. When the variation is greater than the preset value, the accident determination module 16 transmits an alarm signal to the accident alarm module 161. The accidental alarm module 161 receives the alarm signal and then alarms by ringing. The control end 1 can judge the working condition of each diaphragm pump through the flow value in real time, and can give an alarm to remind a user when judging that the diaphragm pump works abnormally.

As shown in fig. 3, the exception handling module 17 receives a start signal or a stop signal output by the individual control module 12. When the accident processing module 17 receives the start signal or the stop signal, the accident processing module 17 calls the alarm signal output by the accident judgment module 16. The accident processing module 17 monitors the state of the accident alarm module 161, and when the accident alarm module 161 alarms and alarms for more than a set time, the accident processing module 17 controls the wireless module 13 to send a signal opposite to the last signal. If the diaphragm pump judged by the control end 1 works abnormally, after a user sends a control signal through the control end 1, the control end 1 sends an alarm and waits, and if the user does not respond, the user automatically removes the further operation on the pin to reduce the loss.

As shown in fig. 4, the control system further includes a report generation module 18, a report storage module 181 and an interface module 19. The report generation module 18 collects the flow value corresponding to the on-off state of each diaphragm pump displayed by the state display module 15 in real time. The report generation module 18 generates a blank report, and the report generation module 18 makes the on-off state into a bitmap and fills the bitmap into the blank report. The report generation module 18 makes the flow value into a curve and fills the curve into a blank report. The report generation module 18 makes the filled blank report into a unit time status report after a set time elapses, and transmits the unit time status report to the report storage module 181. The report storage module 181 receives and stores the unit time status report. The interface module 19 interfaces with a storage device and stores or exports information to the report storage module 181.

The use method comprises the following steps: a user sends a signal to the controlled end 2 through the control end 1 to control the opening and closing of the electromagnetic valve 24, and the user can send a signal to the master control end 3 through the control end 1 to simultaneously control the starting and the closing of all the diaphragm pumps. The controlled end 2 sends the current state of the electromagnetic valve 24 and the flow value of the liquid outlet of the diaphragm pump back to the control end 1 to be displayed for the user. The system can carry out remote wireless control on the diaphragm pumps in any number, does not need manual operation of personnel, and each diaphragm pump has a corresponding serial number, so that the user identification is convenient, and the working condition of each diaphragm pump can be fed back like a user, so that the user can conveniently control the working condition of each diaphragm pump according to the actual condition.

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

Claims (10)

1. A diaphragm pump remote control system characterized in that: the diaphragm pump control system comprises a plurality of electromagnetic valves (24) for controlling the diaphragm pump to work, a control end (1) arranged on mobile equipment and a plurality of controlled ends (2) arranged on the electromagnetic valves (24);

the control end (1) comprises a control wireless module (13), a state display module (15) and an individual control module (12);

the control wireless module (13) is used for receiving and transmitting wireless signals;

the state display module (15) is used for displaying the on-off state of each diaphragm pump;

the independent control module (12) stores the number of each controlled end (2), the independent control module (12) receives an external instruction and transmits the number and a starting signal or a stopping signal to the control wireless module (13), and the control wireless module (13) sends the received starting signal or stopping signal to the controlled end (2) with the corresponding number;

the controlled end (2) comprises a controlled wireless module (21), a start-stop control module (23) and a state feedback module (22);

the controlled wireless module (21) stores a serial number, and the controlled wireless module (21) receives a starting signal or a stopping signal sent by the control wireless module (13) and transmits the starting signal or the stopping signal to the start-stop control module (23);

the start-stop control module (23) receives the start signal and then controls the corresponding electromagnetic valve (24) to be powered on and opened, and the start-stop control module (23) receives the stop signal and then controls the corresponding electromagnetic valve (24) to be powered off and closed;

the state feedback module (22) detects the opening and closing state of the electromagnetic valve (24), when the opening and closing state of the electromagnetic valve (24) changes, the state feedback module (22) sends a current state signal to the controlled wireless module (21) according to the current state of the electromagnetic valve (24), the controlled wireless module (21) sends the current state signal to the control wireless module (13), the control wireless module (13) transmits the current state signal to the state display module (15), and the state display module (15) adjusts the displayed opening and closing state according to the current state signal.

2. A diaphragm pump remote control system according to claim 1, wherein: the electromagnetic valve control system also comprises a main power circuit (33) connected with all the electromagnetic valves (24) and a main control end (3) connected with the main power circuit (33), wherein the main power circuit (33) controls the power supplies of all the electromagnetic valves (24);

the control end (1) further comprises a master control module (11), the master control module (11) receives an external instruction and transmits a master start signal or a master stop signal to the control wireless module (13), and the control wireless module (13) sends the received transmission master start signal or the received transmission master stop signal to the master control end (3);

the master control end (3) comprises a master control wireless module (31) and a power control module (32);

the master control wireless module (31) receives a total starting signal or a total stopping signal sent by the control wireless module (13), and transmits the total starting signal or the total stopping signal to the power supply control module (32);

the power supply control module (32) controls the on-off of the main power supply circuit (33) according to the received total starting signal or total stopping signal.

3. A diaphragm pump remote control system according to claim 2, wherein: the state feedback module (22) comprises a flowmeter (221) arranged at a liquid outlet of the diaphragm pump, the flowmeter (221) is used for detecting a flow value, the state feedback module (22) sends the flow value and a stored serial number to the controlled wireless module (21), the controlled wireless module (21) sends the flow value to the control wireless module (13), the control wireless module (13) transmits the flow value and the serial number to the state display module (15), and the state display module (15) displays the flow value at a corresponding position according to the serial number.

4. A diaphragm pump remote control system according to claim 3, wherein: the control end (1) further comprises a mistaken touch confirmation module (131), the mistaken touch confirmation module (131) receives a starting signal or a stopping signal output by the independent control module (12) and a total starting signal or a total stopping signal output by the total control module (11), the mistaken touch confirmation module (131) intercepts the signals and displays a re-confirmation window after receiving any signals, and the mistaken touch confirmation module (131) stops intercepting after receiving the confirmation signals from the re-confirmation window.

5. A diaphragm pump remote control system according to claim 4, wherein: the control end (1) also comprises an accident judgment module (16) and an accident alarm module (161);

the accident judgment module (16) detects the flow value displayed by the state display module (15) in real time, calculates the variation of the flow value within the set time, compares the variation with a preset value, and transmits an alarm signal to the accident alarm module (161) by the accident judgment module (16) when the variation is larger than the preset value;

and the accidental alarm module (161) receives the alarm signal and then alarms by ringing.

6. A diaphragm pump remote control system according to claim 5, wherein: the control end (1) further comprises an accident processing module (17), the accident processing module (17) receives a starting signal or a stopping signal output by the independent control module (12), when the accident processing module (17) receives the starting signal or the stopping signal, the accident processing module (17) calls an alarm signal output by the accident judging module (16), when the accident processing module (17) monitors the state of the accident alarm module (161), the accident alarm module (161) alarms by ringing and alarms for more than a set time, and the accident processing module (17) controls the wireless module (13) to send a signal opposite to the last sent signal.

7. A diaphragm pump remote control system according to claim 4, wherein: the mistaken touch confirmation module (131) stores various curve graphs, one curve graph is randomly called when the mistaken touch confirmation module (131) displays a re-confirmation window, and the re-confirmation window confirms that a receiving confirmation signal is received when the same information as the called curve graph is input from the outside.

8. A diaphragm pump remote control system according to claim 3, wherein: the control system also comprises a report generation module (18) and a report storage module (181);

the flow value corresponding to the on-off state of each diaphragm pump displayed by the state display module (15) is collected in real time by the report generation module (18), a blank report is generated by the report generation module (18), the on-off state is made into a dot diagram by the report generation module (18) and is filled into the blank report, the flow value is made into a curve diagram by the report generation module (18) and is filled into the blank report, and the filled blank report is made into a unit time state report by the report generation module (18) after a set time, and the unit time state report is transmitted to the report storage module (181);

and the report storage module (181) receives and stores the unit time state report.

9. A diaphragm pump remote control system according to claim 1, wherein: the control end (1) further comprises a pipeline diagram drawing module (14), a pipeline diagram base plate is stored in the pipeline diagram drawing module (14), the pipeline diagram drawing module (14) receives externally input information and generates diaphragm pump icons on the pipeline diagram base plate according to the received information, the pipeline diagram drawing module (14) moves the diaphragm pump icons according to the received information and draws pipeline circuits, a pipeline diagram is finally generated, the pipeline diagram drawing module (14) transmits the pipeline diagram to the state display module (15), and the state display module (15) displays all information on the pipeline diagram.

10. A diaphragm pump remote control system according to claim 8, wherein: the control end (1) further comprises an interface module (19), wherein the interface module (19) is externally connected with a storage device and stores or derives information to the report storage module (181).

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