RU2802098C1 - Ship sewage pumping plant - Google Patents

Abstract

FIELD: sanitary equipment.

SUBSTANCE: intended for pumping wastewater, industrial water and raw sewage not passed through a grate for collecting and pumping a significant amount of wastewater, in all macroclimatic regions on land and at sea, both with moderately cold and tropical maritime climate. The plant for pumping ship sewage, designed for medium-sized river and sea vessels, taking into account cramped conditions of placement, has high reliability with constant monitoring of the continuity of operation due to the presence of upper and working level sensors installed additionally in the receiving tank, associated with pumps, each of which has its own control unit, which ensures continuous and reliable operation of pumps, and all these elements are not only interconnected, but also are under common control by the controller, and, if necessary, can be controlled from the operator's station. The reliability of the proposed plant for pumping ship sewage is also ensured by cyclic flushing of the receiving tank, carried out using a solenoid valve associated with pump control units located in the controller.

EFFECT: creation of a vacuum plant for the collection and pumping of ship sewage, which has high reliability with constant monitoring of the work continuity.

1 cl, 1 dwg

Description

The invention relates to sanitary equipment and is intended for pumping wastewater, industrial water and raw sewage not passed through a grate for collecting and pumping a significant amount of wastewater, in all macroclimatic regions on land and at sea, both with moderately cold, so

with a tropical maritime climate.

The unit is designed specifically for cargo ships, medium-sized river and sea vessels, taking into account cramped placement conditions and stringent requirements for minimum weight and size characteristics.

It is known that the formation of domestic wastewater on vehicles, which include ships of small and medium displacement, is intermittent, which leads to the operation of equipment that ensures the transportation of domestic wastewater in the mode of alternating its on and off, that is, to intermittent operation. depending on the liquid level in the system, thereby causing accelerated wear of all conveying equipment, which generally leads to a decrease in the reliability of the installation.

Known technical solution described in the patent of the Russian Federation No. 2606039, MPKE03C1 / 00, E03F1 / 00, priority dated July 6, 2015 for the invention: “System for assessing and predicting wastewater discharges”.

The system contains a water pumping module, consisting of at least two pumps with suction and pressure pipelines, a receiving tank with a supply pipeline and a shut-off and control device, a module for analyzing diagnosed parameters, containing a block for analyzing water pumping from a receiving tank, a block for probabilistic analysis of water inflow , a block for probabilistic analysis of the total flow of pumps, a block for probabilistic analysis of the cumulative flow of wastewater Q _accum = Q _inc -Q _kns , where Q _inc , Q _kns - are the flow rate of water inflow and the total supply of pumps, a block for analyzing the volume of wastewater discharged into the environment, instrumentation module containing sensors for pumping, pressure, power consumption meter.

The closest analogue in terms of essential features and purpose is the technical solution described in the patent of the Russian Federation No. 2599331, IPC G01F3 / 00, G06Q50 / 00, priority dated May 25, 2015 for the invention: “System for assessing wastewater discharges into the environment”, including a water pumping module containing at least two pumps with suction and pressure pipelines, a receiving tank with a supply pipeline, while the suction pipelines of at least two pumps are connected to the receiving tank, a module for analyzing diagnosed parameters, a module for control and measuring devices containing or at least two pump flow sensors, and/or at least two pressure sensors installed on pressure pipelines, and/or a power consumption meter. All sensors and the power consumption meter of the instrumentation module are equipped with data recording devices and communication channels, a block for inputting volumes of a receiving tank with a communication channel, and a water inflow analysis block. The pump flow sensors are configured to measure the flow rate of each pump, the power consumption meter is configured to measure the current strength and/or power consumption of each pump, the unit for inputting the volumes of the receiving tank and the water inflow analysis unit are included in the module for analyzing the diagnosed parameters. The module for analyzing the diagnosed parameters is additionally equipped with a block for entering the geometric characteristics of the receiving tank, equipped with a communication channel, a block for entering the hydraulic characteristics of the supply pipeline, equipped with a communication channel, a block for analyzing water pumping out of the receiving tank, equipped with a data recording device and a communication channel, a block for probabilistic analysis of water inflow, equipped with a communication channel, a block for probabilistic analysis of the total supply of pumps, equipped with a communication channel, a block for inputting probabilistic and technological indicators of the reliability _of pumps, _equipped with a _{communication channel} , a _block for probabilistic analysis of the cumulative flow of wastewater flow rate of water inflow and total flow of pumps, equipped with a communication channel, a block for analyzing the volume of wastewater discharged into the environment, the block for analyzing water inflow is additionally equipped with two communication channels connecting its output with the inputs of the block for probabilistic analysis of water inflow and the block for analyzing the volume of wastewater discharged into the environment environment, the output of the block for probabilistic analysis of water inflow is connected via a communication channel to the input of the block for probabilistic analysis of the accumulative flow of wastewater, and the output of the block for input of probabilistic and technological indicators of the reliability of pumps is connected via a communication channel to the input of the block for probabilistic analysis of the total flow of pumps, the output of the block for probabilistic analysis total pump flow is connected via a communication channel to the input of the unit for probabilistic analysis of the cumulative flow of wastewater, the output of which is connected via a communication channel to the input of the unit for analyzing the volume of wastewater discharged into the environment. The instrumentation module is additionally equipped with a water level sensor installed on the supply pipeline and a water level sensor installed in the receiving tank, equipped with data recording devices and communication channels. The water pumping module is additionally equipped with a shut-off and control device with an actuator installed on the supply pipeline between the water level sensor installed on the supply pipeline and a receiving tank, a control device equipped with a communication channel. The unit for probabilistic analysis of the cumulative wastewater flow is configured to determine the probability density function of the cumulative flow. The water inflow analysis unit is configured to determine the schedule of water inflow entering the inlet pipeline in front of the receiving tank, and the correlation between the duration of the inlet pipeline flooding and the cumulative flow rate Q of the wastewater _storage , the output of the data recorder of the water level sensor installed in the receiving tank, using channels connection is connected to the input of the control device and the input of the water inflow analysis unit, the output of the control device is connected to the input of the executive body of the shut-off and control device. The control device is configured to generate control signals to the executive body of the shut-off and control device, the output of the block for inputting the volume of the receiving tank, the outputs of the data recording devices of at least two pump flow sensors, two pressure sensors and a power consumption meter are connected via communication channels to the input of the analysis unit for pumping water from the receiving tank, the output of the data recorder of the water level sensor installed on the inlet pipeline is connected to the input of the water inflow analysis unit by means of a communication channel, the outputs of the blocks for entering the geometric characteristics of the receiving tank, the input of the hydraulic characteristics of the supply pipeline and the data recording device the analysis unit for pumping water from the receiving tank is connected to the input of the water inflow analysis unit using communication channels.

The disadvantage of the known technical solution described above is that it does not have high reliability, since it does not provide constant monitoring of the continuity of operation, as well as monitoring that occurs during the operation of the system. errors, since the failure of the only sensor installed in the receiving tank does not allow to constantly monitor the process of pumping wastewater, which must be done taking into account the cramped conditions for placing the receiving tank in medium-sized river and sea vessels.

In addition, in the known technical solution there is no possibility of periodic flushing of the receiving tank, which also reduces the reliability of the device as a whole.

The objective of the claimed invention is to create a plant for pumping ship sewage, which has high reliability with constant monitoring of the continuity of work.

The problem is solved due to the fact that the installation for pumping ship sewage, containing the first and second pumps connected by the first inputs through pipelines to the receiving tank, the first input of which is connected through the pipeline with effluents from the sewage system, in the receiving tank there is a sensor of the lower filling level water, as well as the control unit according to the invention additionally contains sensors for the upper and working levels of water filling installed in the receiving tank, an electromagnetic valve for washing the receiving tank, connected by the first inlet to the water supply, and by the output - to the inlet of the receiving tank, while the control unit is made in the form a controller containing control units for the operation of the first and second pumps, blocks for shutting down the first and second pumps during continuous operation for more than 15 minutes, a block for changing the order of starting the first and second pumps and delaying the start of the backup pump, the first input of the control unit for the operation of the first pump being the first input of the controller is connected to the first output of the first pump and through the first output of the controller is connected to the operator's station, the second input of the control unit for the operation of the first pump is connected to the first output of the shutdown unit of the first pump, the input of which, being the second input of the controller, is connected to the second output of the first pump, the third the input of the control unit for the operation of the first pump is connected to the first output of the pump start sequence block, the first input of which is connected to the output of the control unit for the operation of the first pump, which is the second output of the controller, which is connected to the second input of the first pump and to the second input of the valve for flushing the receiving tank, the fourth input the control unit for the operation of the first pump is connected to the first input of the control unit for the operation of the second pump, which is the third input of the controller, is connected to the output of the low water level sensor, the fifth input of the control unit for the operation of the first pump is connected to the second input of the control unit for the operation of the second pump, which is the fourth input of the controller and is connected to the output of the sensor of the working level of water filling, the sixth input of the control unit for the operation of the first pump connected to the third input of the control unit for the operation of the second pump, which is the fifth input of the controller, is connected to the “emergency shutdown” channel, and is also connected through the third output of the controller to the operator’s station, the seventh input of the node for controlling the operation of the first pump is connected to the fourth input of the node, which is the sixth input of the controller and is connected to the output of the sensor of the upper level of water filling , and also through the fourth output of the controller is connected to the operator's station, the eighth input of the first pump operation control unit is connected to the eighth input of the second pump operation control unit, which is the ninth input of the controller associated with the “automatic mode activation” channel, the fifth input of the second pump operation control unit is connected to the first output of the second pump shutdown unit during continuous operation for more than 15 minutes , the second output of which is connected to the second output of the block for shutting off the first pump during continuous operation for more than 15 minutes and through the fifth output of the controller is connected to the operator’s station, while the input of the block for shutting off the second pump during continuous operation for more than 15 minutes, which is the seventh input of the controller, is connected to the first output of the second pump, the second output of which, through the eighth input of the controller, is connected to the sixth input of the control unit for the operation of the second pump and through the sixth output of the controller is connected to the operator’s station, the seventh input of the control unit for the operation of the second pump is connected to the second output of the block for changing the order of starting the pumps and delaying the start of the backup pump, the second input of which is connected to the output of the control unit for the operation of the second pump and is connected through the seventh output of the controller to the second input of the second pump, and to the second input of the pumping electromagnetic valve, the third outputs of the first and second pumps being combined and connected to the drain system.

The drawing shows a block diagram of a plant for pumping ship sewage. In accordance with the drawing, the installation for pumping ship sewage contains the first 6 and second 7 pumps connected by the first inputs through pipelines to the receiving tank 2, the input of which is connected through the pipeline with effluent from the sewerage system. The sensors 3, 4 and 5, respectively, of the upper, working and lower levels are installed in the receiving tank 2, the input of which is connected to the output of the solenoid valve 1 for washing the receiving tank 2, the first input of the valve 1 is connected to the water supply. The control unit is made in the form of a controller 8, containing units 11, 13 for controlling the operation of the first and second pumps 6, 7, blocks 9, 12 for shutting down the first and second pumps 6, 7 during continuous operation for more than 15 minutes, a block 10 for changing the order of starting the first and second pumps 6, 7 and a delay in starting the backup pump, the first input of the node 11 controlling the operation of the first pump, which is the first input of the controller 8, is connected to the first output of the first pump 6,and through the first output of the controller 8 is connected to the operator's station, the second input of the node 11 to control the operation of the first pump 6 is connected to the first output of the block 9 of the shutdown of the first pump 6, the input of which is the second input of the controller 8, is connected to the second output of the first pump 6, the third input of the node 11 to control the operation of the first pump 6 is connected to the first output of the block 10 of the order of starting pumps 6, 7, the first input of which is connected to the output of the node 11 of the control of the operation of the first pump 6, which is the second output of the controller 8, which is connected to the second input of the first pump 6 and with the second input of the valve 1 for flushing the receiving tank 2, the fourth input of the node 11 for controlling the operation of the first pump 6 is connected to the first input of the node 13 for controlling the operation of the second pump 7, which is the third input of the controller 8, is connected to the output of the lower water level sensor 5, the fifth input of the node 11 to control the operation of the first pump 6 is connected to the second input of the node 13 to control the operation of the second pump 7, which is the fourth input of the controller 8 and is connected to the output of the sensor 4 of the working level of water filling, the sixth input of the node 11 control of the operation of the first pump 6 is connected to the third input of the node 13 to control the operation of the second pump 7, which is the fifth input of the controller 8, is connected to the "emergency shutdown" channel, and is also connected through the third output of the controller 8 to the operator's station, the seventh input of the node 11 to control the operation of the first pump 6 is connected to the fourth input of the node 13 to control the operation of the second pump 7, which is the sixth input of the controller 8 and is connected to the output of the sensor 3 of the upper level of water filling, and also through the fourth output of the controller 8 is connected to the operator's station, the eighth input of the node 11 to control the operation of the first pump 6 is connected to the eighth input of the node 13 to control the operation of the second pump 7, which is the ninth input of the controller 8 associated with the channel "turn on the automatic mode", the fifth input unit 12 for controlling the operation of the second pump 7 is connected to the first output of the block 12 for shutting down the second pump 7 during continuous operation for more than 15 minutes, the second output of which is connected to the second output of the block 9 for shutting down the first pump 6 during continuous operation for more than 15 minutes and through the fifth output of the controller 8 is connected with the operator's station, while the input of the block 12 shutdown of the second pump 7 during continuous operation for more than 15 minutes, which is the seventh input of the controller 8, is connected to the first output of the second pump 7, the second output of which, through the eighth input of the controller 8, is connected to the sixth input of the work control unit 13 of the second pump 7 and through the sixth output of the controller 8 is connected to the operator's station, the seventh input of the node 13 for controlling the operation of the second pump 7 is connected to the second output of the block 10 for changing the order of starting the pumps and delaying the start of the backup pump, the second input of which is connected to the output of the node 13 for controlling the operation of the second pump 7 and through the seventh output of the controller 8 is connected to the second input of the second pump 7 evacuation and the second input of the solenoid valve 1 evacuation, and the third outputs of the first 6 and second 7 pumps are combined and connected to the drain system.

Installation for pumping ship sewage operates as follows.

To start one of the pumps, it is necessary to send a signal “enable automatic mode” to input 8 control unit 11 with the first pump 6 and at the inlet 8 of the control unit 13 with the second pump 7. The receiving tank 2 is filled with sewage. When the liquid level in the receiving tank 2 of the lower level sensor 5 is reached, the sensor sends a signal to the nodes of the controller 8: to the input 4 of the control unit 11 by the first pump 6 and to the input 1 of the control unit 13 by the second pump 7. Further, when the liquid level in the receiving tank 2 of the sensor is reached operating level 4, the sensor is triggered and outputs a signal to input 5 of node 11 of the control of the first pump 6 and input 2 13 of the control node of the second pump 7. The unit 10 for changing the order of starting the pumps and delaying the start of the backup pump controls the operation of pumps 6 and 7, receiving signals from the nodes 11, 13 control pumps 6,7 and gives a signal to start the first pump 6 and with a delay of 5 seconds gives a signal to start the second pump 7. In this case, the input 3 of the node 11 of the pump control 6 receives a signal from the output of the block 10. As a result, the output node 11, a signal appears that starts pump 6. After 5 seconds, unit 10 sends a signal to input 7 of node 13 to control the second pump 7, as a result, a signal appears at the output of node 13 to start pump 7. Pumps 6 and 7 operate simultaneously and pump out liquid from receiving tank 2. The level in the receiving tank 2 decreases and the signals of the working level sensor 4 and the lower level sensor 5 are successively switched off. When the signal of the low level sensor 5 is turned off, the signals at the output of control units 11 and 13 are turned off, and pumps 6 and 7 are also turned off. 7 and does not issue a start permission signal to the input 3 of the control unit 11 of the first pump 6. Wastewater is collected in the receiving tank 2, while the level in the receiving tank 2 grows and, reaching the working level sensor 4, the signal from the sensor 4 turns on the input 2 of the node 13 control of the second pump 7. This starts the second pump 7 and then after 5 seconds the block 10 sends a signal to the input 5 of the node 11 and the pump 6 is turned on. is changing.

To prevent overflow of the receiving tank 2, an upper level sensor 3 is provided. When the liquid level in the receiving tank 2 rises to the upper level sensor 3, the sensor generates a signal that is fed to input 7 of node 11, input 4 of node 13 of controller 8. In this case, the outputs of these nodes turn on and signals are received at the inputs of pumps 6,7, they turn on, and the collection of liquid in the receiving tank 2 continues.

To protect the pumps from an accident on the pumping line (clogging), automatic shutdown of the pumps is provided for continuous operation of the pumps for more than 10 minutes.

When the pumps 6, 7 are operating, they send a pump operation signal to the blocks 9 and 12 of the pump shutdown delay during prolonged operation of the controller 8. If the signal is given for more than 10 minutes, then a signal appears at the output of nodes 9 and 12, which is then transmitted to input 2 of node 11 and input 5 of node 13, while the signal is turned off at the output of control nodes 11 and 13, as a result, pumps 6 are turned off .7.

If a signal about a malfunction of pumps 6 or 7 occurs, their shutdown is provided. Malfunction signals from pumps 6 or 7 are fed to input 1 of node 11 of control of the first pump 6 or to input 6 of node 13 of control of the second pump 7, while the signals at the outputs of node 11 of control of the first pump 6 or node 13 of control of the second pump 7 are turned off, which, as a result, turns off pumps 6 or 7.

When an “emergency shutdown” signal occurs, which is fed to input 6 of node 11 of the control of the first pump 6, input 3 of the node 13 of control of the second pump 7, while the signal at the outputs of these nodes is turned off, which causes the pumps 6 and 7 to stop.

Flushing of the receiving tank 2 is carried out in accordance with the alternation of the plant operation cycles.

In the first cycle of the plant operation, the receiving tank 2 is flushed as follows. Simultaneously with the signal to turn on pump 6, a signal from node 11 is sent to valve 1 for flushing the receiving tank 2. When a signal is received from block 11, valve 1 opens and water from the water supply system flows to flush the receiving tank 2. When the signal from node 13 is repeated, valve 1 does not reacts to it and remains in the open position. When pumps 6 and 7 are turned off simultaneously, the signal from units 11 and 13 is simultaneously turned off and valve 1 closes, flushing of the receiving tank ends.

In the next cycle of the installation, the receiving tank 2 is flushed as follows. Simultaneously with the signal to turn on pump 7, a signal from node 13 is sent to valve 1 for flushing the receiving tank 2. When a signal is received from unit 13, valve 1 opens and water from the water supply system flows to flush the receiving tank 2. When the signal from node 11 is repeated, valve 1 does not reacts to it and remains in the open position. When pumps 6 and 7 are turned off simultaneously, the signal from units 11 and 13 is simultaneously turned off and valve 1 closes, flushing of receiving tank 2 ends.

The system also provides for communication with the operator's station, and the alarm for the operator turns on under the following conditions: the level of wastewater in the receiving tank 2 has reached the upper level sensor 3; occurrence of malfunction of pumps 6.7; shutdown of pumps 6.7 during long-term operation; when an emergency stop signal is received.

- When the upper level sensor 3 is triggered, the signal goes to the controller 8 and then to the operator's station controlling the installation (not shown in the diagram).

- In the event of a malfunction of the first pump 6 or the second pump 7, the signals from the pumps go to the controller 8 and then to the operator's station (not shown in the diagram).

- When the first pump 6 is operating, a signal about its operation is sent to the block 9 for shutting down the first pump 6. If the first pump 6 has been running continuously for more than 10 minutes, then a signal appears at the output of block 9, which is sent to the operator's station (not shown in the diagram).

- When the second pump 7 is operating, a signal about its operation is sent to the block 12 for shutting down the second pump 7. If the second pump 7 has been running continuously for more than 10 minutes, a signal occurs at the output of block 12, which is sent to the operator's station

(not shown in the diagram).

- When the “emergency shutdown” signal is given, the signal goes to the controller 8 and then to the operator’s station (not shown in the diagram).

Upon receiving a signal about a malfunction, the operator approaches the unit, inspects it and decides to carry out work to repair the unit.

The inventive installation for pumping ship sewage, designed for medium-sized river and sea vessels, taking into account cramped conditions of placement, is highly reliable with constant monitoring of the continuity of operation compared to the closest analogue due to the presence of additional sensors installed in the receiving tank of the upper and working levels associated with pumping pumps, each of which has its own control unit, which ensures continuous and reliable operation of the pumping pumps, and all these elements are not only interconnected, but also under common control by the controller, and, if necessary, can be controlled from the post operator.

The reliability of the proposed installation for pumping ship sewage is also ensured by cyclic flushing of the receiving tank, carried out using a solenoid valve associated with pump control units located in the controller.

Claims (1)

Installation for pumping ship sewage, containing the first and second pumps connected by the first inputs through pipelines to the receiving tank, the first input of which is connected through the pipeline with effluents from the sewerage system, in the receiving tank there is a sensor of the lower filling level of water, as well as a control unit, which differs the fact that it additionally contains sensors for the upper and working levels of water filling installed in the receiving tank, an electromagnetic valve for washing the receiving tank, connected by the first inlet to the water supply, and by the output - to the inlet of the receiving tank, while the control unit is made in the form of a controller containing control units operation of the first and second pumps, blocks for shutting down the first and second pumps during continuous operation for more than 15 minutes, a block for changing the order of starting the first and second pumps and delaying the start of the backup pump, the first input of the control unit for the operation of the first pump, which is the first input of the controller, is connected to the first by the output of the first pump and through the first output of the controller is connected to the operator's station, the second input of the control unit for the operation of the first pump is connected to the first output of the shutdown block of the first pump, the input of which, which is the second input of the controller, is connected to the second output of the first pump, the third input of the control unit for the operation of the first of the pump is connected to the first output of the pump start sequence block, the first input of which is connected to the output of the first pump operation control unit, which is the second output of the controller, which is connected to the second input of the first pump and to the second input of the receiving tank flushing valve, the fourth input of the first pump operation control unit connected to the first input of the second pump operation control unit, which is the third input of the controller, is connected to the low water level sensor output, the fifth input of the first pump operation control unit is connected to the second input of the second pump operation control unit, which is the fourth controller input, and is connected to the sensor output operating level of water filling, the sixth input of the first pump operation control unit is connected to the third input of the second pump operation control unit, which is the fifth input of the controller, is connected to the "emergency shutdown" channel and is also connected through the third output of the controller to the operator's station, the seventh input of the operation control unit of the first pump is connected to the fourth input of the second pump operation control unit, which is the sixth input of the controller, and is connected to the output of the upper water level sensor, and is also connected to the operator’s station through the fourth controller output, the eighth input of the first pump operation control unit is connected to the eighth input of the unit control of the operation of the second pump, which is the ninth input of the controller associated with the channel "turn on the automatic mode", the fifth input of the control unit for the operation of the second pump is connected to the first output of the shutdown unit of the second pump during continuous operation for more than 15 minutes, the second output of which is connected to the second output of the shutdown unit of the first pump during continuous operation for more than 15 minutes and through the fifth output of the controller is connected to the operator's station, while the input of the shutdown block of the second pump during continuous operation for more than 15 minutes, which is the seventh input of the controller, is connected to the first output of the second pump, the second output of which is through the eighth input of the controller is connected to the sixth input of the second pump operation control unit and through the sixth output of the controller is connected to the operator's station, the seventh input of the second pump operation control unit is connected to the second output of the unit for changing the order of starting the pumps and delaying the start of the backup pump, the second input of which is connected to the output of the control unit operation of the second pump and through the seventh output of the controller is connected to the second input of the second pump and to the second input of the pumping electromagnetic valve, and the third outputs of the first and second pumps are combined and connected to the drain system.

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