CN112506128A - Unmanned life supply and sewage recovery control system - Google Patents

Abstract

The invention discloses an unmanned life supply and sewage recovery control system, which belongs to the field of ship automation.A IC card collector is used for collecting and storing user information, and a human-computer interaction interface is used for controlling the system to work; the water adding module comprises a flowmeter arranged in the water adding pipe and used for displaying the flow rate of the domestic water in real time, and an electric valve arranged on the water adding pipe and used for controlling the starting and stopping of water adding; the radar liquid level meter is arranged in the sewage tank, and the electric valve is arranged in the sewage collecting pipe; the electric energy metering device is arranged at the input end of the power supply, is used for recording the supplied electric quantity, and is arranged on the air switch of the coil; a flow meter installed in the oil filling pipe for displaying the flow rate of the oil in real time; and the electric valve is arranged in the oil filling pipe and is used for controlling the starting and stopping of oil filling. The invention has the beneficial effects that: the service provided by the system is more perfect; operations such as replenishment, sewage recovery and the like are not required to be carried out by operators, so that the cost is reduced; service many boats, promoted efficiency.

Description

Unmanned life supply and sewage recovery control system

Technical Field

The invention relates to the field of ship automation, in particular to an unmanned life supply and sewage recovery control system

Background

At present, most wharfs in the Yangtze river can only add domestic water and collect dirty functions, and operating personnel in the wharfs are required to operate a domestic water adding mode and a sewage recovery mode.

The existing scheme can only supply domestic water for ships and recover sewage, but cannot meet the requirements of other types of ships, such as power supply, refueling and the like; operators in the pontoon carry out operations such as replenishment, sewage recovery and the like, so the cost is high; operations such as replenishment, sewage recovery and the like can be performed only on a single ship, and a plurality of ships cannot be operated simultaneously, so that the efficiency is low.

Disclosure of Invention

In order to better solve the technical problem, the present application provides an unmanned life supply and sewage recovery control system, including: the sewage treatment system comprises a water adding module, a sewage tank, a power supply module and an oil supply module; an IC card collector is arranged in an operating room in the pontoon and is used for collecting and storing user information and deducting fees; the human-computer interaction interface is arranged beside the IC card collector and provides options of domestic water supply, sewage recovery, power supply and oil supply to control the system to work; the water adding module comprises a flowmeter arranged in a water adding pipe, an electric valve arranged in the water adding pipe and used for controlling the starting and stopping of water adding, wherein the flowmeter is used for displaying the flow rate of domestic water in real time; the sewage tank comprises a radar liquid level meter arranged in the sewage tank and used for displaying the real-time liquid level of the sewage; the electric valve is arranged in the sewage collecting pipe and is used for controlling the starting and stopping of sewage collection; the power supply module comprises an electric energy metering device arranged at the input end of the power supply, an air switch arranged on the coil and used for recording the supplied electric quantity and controlling the starting and stopping of the power supply;

the oil supply module comprises a flowmeter arranged in the oil filling pipe and is used for displaying the flow rate of oil in real time; and the electric valve is arranged in the oil filling pipe and is used for controlling the starting and stopping of oil filling.

Preferably, the human-computer interaction interface is a software LabVIEW-based human-computer interaction interface, provides options of domestic water supply, sewage recovery, power supply and oil supply, and further comprises a data information acquisition module for acquiring user data and an intelligent database module for storing and analyzing the user data.

Preferably, the intelligent database module comprises an SQL-based database, and consists of an information acquisition database, a domestic water supply database, a sewage recovery database, a power supply database and an oil supply database, wherein the human-computer interaction interface is connected with the intelligent database, displays the data sent by the intelligent database module, and sends an operation instruction to the intelligent database; the operation instruction comprises database name query, time node query, data addition and data deletion.

Preferably, the data information acquisition module comprises a PLC module, the acquired water adding amount data, sewage liquid level data, oil supply amount data and power supply amount data are transmitted to the PLC module, the PLC and the LabVIEW establish communication after the data are processed by the PLC, and the data are transmitted to the human-computer interaction interface; and identifying the user information through the IC card collector, and storing data and deducting fee.

Preferably, the water adding real-time price formula displayed by the human-computer interaction interface is calculated as follows:

Pr_x＝H·L；

wherein x represents the number of the water filling port and is represented by 1, 2, 3 …, H represents the unit price of water filling, L represents the flow rate of water filling measured by the flowmeter, and Pr represents the total cost of water filling.

Preferably, the real-time pollution collection price formula is calculated as follows:

V＝32.34L-V′；

J_x＝KV；

wherein, x represents the serial number of the sewage collecting port, L represents the liquid height of the sewage tank measured by the radar position finder, V represents the net volume of the sewage tank, V' represents the net volume of the previous sewage tank, K represents the unit price of sewage collection, and J represents the total price of sewage collection.

Preferably, the real-time price formula of fuel supply is calculated as follows:

Py_x＝U·Z；

wherein x represents the serial number of the oil feeding water filling port and is represented by 1, 2 and 3 …, U represents the unit price of water filling, Z represents the flow rate of water filling measured by the flowmeter, and Py represents the total cost of oil feeding.

Preferably, the power supply real-time price formula is calculated as follows:

Q_x＝N·M

wherein x represents the serial number of the power supply port, N represents the power supply amount, M represents the unit price of the power supply amount, and Q represents the total cost of the power supply.

The invention has the beneficial effects that:

the integral solution of the supply of the domestic water of the ship, the recovery of the sewage, the power supply and the oiling is provided, so that the service provided by the system is more complete;

operations such as replenishment, sewage recovery and the like are not needed in the pontoon, so that the hiring cost can be reduced, and the cost is reduced;

the existing scheme can supply domestic water, recover sewage, supply power and supply oil to a plurality of ships, and service efficiency is improved.

Drawings

FIG. 1 is a schematic view of a connection structure of a console;

fig. 2 is a schematic diagram of the overall structure of the control system of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

An unmanned life supply and sewage recovery control system comprising: the sewage treatment system comprises a water adding module, a sewage tank, a power supply module and an oil supply module; an IC card collector is arranged in an operating room in the pontoon and is used for collecting and storing user information and deducting fees; the human-computer interaction interface is arranged beside the IC card collector and provides options of domestic water supply, sewage recovery, power supply and oil supply to control the system to work; the water adding module comprises a flowmeter arranged in a water adding pipe, an electric valve arranged in the water adding pipe and used for controlling the starting and stopping of water adding, wherein the flowmeter is used for displaying the flow rate of domestic water in real time; the sewage tank comprises a radar liquid level meter arranged in the sewage tank and used for displaying the real-time liquid level of the sewage; the electric valve is arranged in the sewage collecting pipe and is used for controlling the starting and stopping of sewage collection; the power supply module comprises an electric energy metering device arranged at the input end of the power supply, an air switch arranged on the coil and used for recording the supplied electric quantity and controlling the starting and stopping of the power supply; the oil supply module comprises a flowmeter arranged in the oil filling pipe and is used for displaying the flow rate of oil in real time; and the electric valve is arranged in the oil filling pipe and is used for controlling the starting and stopping of oil filling.

The human-computer interaction interface is a software LabVIEW-based human-computer interaction interface, provides options of domestic water supply, sewage recovery, power supply and oil supply, and further comprises a data information acquisition module for acquiring user data and an intelligent database module for storing and analyzing the user data.

The intelligent database module comprises an SQL-based database, and consists of an information acquisition database, a domestic water supply database, a sewage recovery database, a power supply database and an oil supply database, wherein a human-computer interaction interface is connected with the intelligent database, displays data sent by the intelligent database module, and sends an operation instruction to the intelligent database; the operation instruction comprises database name query, time node query, data addition and data deletion.

The data information acquisition module comprises a PLC module, the acquired water adding amount data, the acquired sewage liquid level data, the acquired oil supply amount data and the acquired power supply amount data are transmitted to the PLC module, the PLC establishes communication with the LabVIEW after the data are processed by the PLC, and the data are transmitted to a human-computer interaction interface; and identifying the user information through the IC card collector, and storing data and deducting fee.

The water adding real-time price formula displayed by the human-computer interaction interface is calculated as follows:

Pr_x＝H·L；

wherein x represents the number of the water filling port and is represented by 1, 2, 3 …, H represents the unit price of water filling, L represents the flow rate of water filling measured by the flowmeter, and Pr represents the total cost of water filling.

The real-time pollution collection price formula is calculated as follows:

V＝32.34L-V′；

J_x＝KV；

wherein, x represents the serial number of the sewage collecting port, L represents the liquid height of the sewage tank measured by the radar position finder, V represents the net volume of the sewage tank, V' represents the net volume of the previous sewage tank, K represents the unit price of sewage collection, and J represents the total price of sewage collection.

The real-time price formula for oil supply is calculated as follows:

Py_x＝U·Z；

wherein x represents the serial number of the oil feeding water filling port and is represented by 1, 2 and 3 …, U represents the unit price of water filling, Z represents the flow rate of water filling measured by the flowmeter, and Py represents the total cost of oil feeding. The power supply real-time price formula is calculated as follows:

Q_x＝N·M

wherein x represents the serial number of the power supply port, N represents the power supply amount, M represents the unit price of the power supply amount, and Q represents the total cost of the power supply.

Claims (8)

1. The utility model provides an unmanned life supply and sewage recovery control system which characterized in that includes:

the sewage treatment system comprises a water adding module, a sewage tank, a power supply module and an oil supply module; an IC card collector is arranged in an operating room in the pontoon and is used for collecting and storing user information and deducting fees; the human-computer interaction interface is arranged beside the IC card collector and provides options of domestic water supply, sewage recovery, power supply and oil supply to control the system to work; the water adding module comprises a flowmeter arranged in a water adding pipe, an electric valve arranged in the water adding pipe and used for controlling the starting and stopping of water adding, wherein the flowmeter is used for displaying the flow rate of domestic water in real time; the sewage tank comprises a radar liquid level meter arranged in the sewage tank and used for displaying the real-time liquid level of the sewage; the electric valve is arranged in the sewage collecting pipe and is used for controlling the starting and stopping of sewage collection; the power supply module comprises an electric energy metering device arranged at the input end of the power supply, an air switch arranged on the coil and used for recording the supplied electric quantity and controlling the starting and stopping of the power supply; the oil supply module comprises a flowmeter arranged in the oil filling pipe and is used for displaying the flow rate of oil in real time; and the electric valve is arranged in the oil filling pipe and is used for controlling the starting and stopping of oil filling.

2. The system of claim 1, wherein the human-machine interface is a software LabVIEW-based human-machine interface providing options for domestic water supply, wastewater recovery, power supply and oil supply, and further comprising a data information collection module for collecting user data and an intelligent database module for storing and analyzing the user data.

3. The unmanned domestic feeding and sewage recovery control system of claim 2, wherein said intelligent database module comprises an SQL-based database, which is composed of an information acquisition database, a domestic water feeding database, a sewage recovery database, a power supply database and an oil supply database, wherein the human-computer interaction interface is connected with the intelligent database, displays the data sent by the intelligent database module, and sends an operation instruction to the intelligent database; the operation instruction comprises database name query, time node query, data addition and data deletion.

4. The unmanned life supply and sewage recovery control system of claim 2, wherein the data information collection module comprises a PLC module, and the collected water addition amount data, sewage level data, oil supply amount data and power supply amount data are transmitted to the PLC module, and after the data are processed by the PLC, the PLC establishes communication with the LabVIEW, and the data are transmitted to the human-computer interaction interface; and identifying the user information through the IC card collector, and storing data and deducting fee.

5. The system of claim 2, wherein the real-time price formula for water addition displayed on the human-computer interface is calculated as follows:

Pr_x＝H·L；

wherein x represents the number of the water filling port and is represented by 1, 2, 3 …, H represents the unit price of water filling, L represents the flow rate of water filling measured by the flowmeter, and Pr represents the total cost of water filling.

6. The unmanned life supply and sewage recovery control system of claim 2 wherein the real-time price of sewage collection is calculated as follows:

V＝32.34L-V′；

J_x＝KV；

wherein, x represents the serial number of the sewage collecting port, L represents the liquid height of the sewage tank measured by the radar position finder, V represents the net volume of the sewage tank, V' represents the net volume of the previous sewage tank, K represents the unit price of sewage collection, and J represents the total price of sewage collection.

7. The unmanned life supply and sewage recovery control system of claim 2, wherein the fuel supply real-time price formula is calculated as follows:

Py_x＝U·Z；

wherein x represents the serial number of the oil feeding water filling port and is represented by 1, 2 and 3 …, U represents the unit price of water filling, Z represents the flow rate of water filling measured by the flowmeter, and Py represents the total cost of oil feeding.

8. The unmanned domestic replenishment and sewage recovery control system of claim 2, wherein said power supply real-time price formula is calculated as follows:

Q_x＝N·M

wherein x represents the serial number of the power supply port, N represents the power supply amount, M represents the unit price of the power supply amount, and Q represents the total cost of the power supply.

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