UA26658U - Automated system for control of pump station of municipal water supply system - Google Patents

Abstract

An automated system for control of pump station of municipal water supply system includes pressure sensor, pressure controller and switch block, control cabinet, frequency converter for main pump unit, appliance of smooth for backup pump unit, control panel and control circuit.

Description

Description of the invention

The useful model refers to the water supply industry, in particular, to the control systems of city pumping stations 2 working on the water distribution network.

It is known that regulation of the performance of pump units can be carried out by influencing the turbomechanism (rotating the blades of the impeller), influencing the communication network (throttling with a valve), influencing the drive of the turbomechanism (changing the speed of rotation of the impeller of one of the pumps), as well as changing the number of units that work simultaneously.

At the same time, the main requirements for the system of regulating the output parameters of turbomechanisms are to ensure the specified nature of the change in productivity of the consumer, to maintain the pressure at the required level, and to ensure the efficiency and reliability of the installation.

Regulation of the performance of the pumping unit by influencing the communication network by changing the hydrodynamic resistance of the pipeline system with the help of a throttle is accompanied by a significant decrease of 12 the efficiency of the mechanism, the presence of non-productive energy losses.

When the turbo unit is affected, there is a change in productivity by turning the blades of the impeller by the guide apparatus. The efficiency of the pump with this adjustment is significantly higher than with throttling, however, the use of a guide device significantly complicates the construction and maintenance of the installation.

In this regard, there was a need to find ways to regulate the productivity of pumping stations, which are not inferior to the known traditional methods of regulation in terms of their regulation capabilities and differ in higher energy and economic indicators.

The effect on the turbomechanism drive is the least energy-consuming way, which increases the quality of the adjustment of the output parameters, which requires the installation of a transforming minor modernization of the entire installation.

The pumping station performance management system is known from (Russian Patent Mo2056480, published in 1996, 2 July). It implements a method of regulating the pressure in the water supply network based on the signals of measurement information, which indirectly characterizes the intensity of water consumption by individual consumers. The system includes two control loops - internal and external. The internal circuit of local pressure regulation at the outlet of the pumping station contains a manometer, a comparison element, a regulator and an electric drive. The external circuit for regulating the performance of the pumping station has a distributed system of sensors for the state of secondary automation, designed to regulate the flow of water at consumers, an adder of signals from sensors and an integrator.

The advantage of the known system is that it provides for the collection and processing of information about the state of not only the water supply station itself, but also the water supply area, thanks to which water supply is coordinated according to Ge) real, not expected, needs. The system ensures the maintenance of pressure levels in consumer installations, set by the consumers themselves, using as sources of measurement information sensors of the angle of rotation of the executive control bodies of the secondary circuits of pressure regulation at consumers.

The disadvantage of the known system is its narrow selectivity regarding the type of consumers. Namely, it justifies itself when it comes to industrial consumers who use water for technological needs. The /«f system can be implemented only at consumers whose technological equipment is equipped with local automation Z 70 regulation of water consumption, moreover, of a certain structural type. This requirement limits the range of possible application of the system, in particular, it cannot be used effectively at pumping stations of the city's water supply system, which serve mainly domestic consumers.

Management of water use by this category of consumers represents the greatest difficulties for water network managers. In fact, no restrictive measures are applied to it, and traditionally domestic consumers are allowed to consume water according to a free daily schedule according to their needs, which change according to the natural daily cycle of fluctuations in people's household activity.

Gee! The closest in terms of technical substance to the proposed solution (the closest analog) is a device for automatic regulation of the operation of the pumping station according to |Author's Certificate of the USSR Mo1028796А, b published in 1983|, which contains a pressure sensor in the pressure pipeline, a pressure sensor, both sl 20 are connected with a comparison unit, as well as a pump station productivity control unit. The device also contains a timer, a switching unit and a unit for forced reduction of the pumping station's productivity. The described device provides for a forced reduction in the productivity of the pumping station by closing the valves on one of the group of pumps operating in parallel, followed by the shutdown of this pump, provided that the closing of the valves did not lead to a decrease in the pressure in the pressure pipeline below the permissible level. 25 The disadvantage of the known device is that it works according to a rigid time schedule set with a timer, while ignoring real fluctuations in consumer demand for water at different hours of the day. In those cases when the forced reduction of productivity occurs against the background of a decrease in the need for water, for example, in the evening, the operation of the system leads to the minimization of the number of activated pumps. If the device initiates an attempt to reduce the productivity of the pumping station during the period of intensive water analysis by consumers, the device excites 60 pressure fluctuations in the external network, idle operation of the valves, which ultimately leads to an increase in their wear. The variability of the daily dynamics of changes in the demand for water in the utility sector (KPS), its susceptibility to the influence of seasonal factors (weather factors) complicates the adjustment of the device and reduces its efficiency. As a result, the indicated shortcomings lead to wear and tear of pump station equipment, excessive energy consumption and inefficient supply of water to consumers. because the proposed useful model is devoid of the above-mentioned shortcomings.

The task of the useful model is to create a pump station control system that will allow: - to significantly reduce energy consumption due to the optimal torque control algorithm of the electric motor of the pumping unit; - to reduce starting currents during start-up and during the operation of electric motors of the pumping unit due to smooth start-up and acceleration of the pumping unit; - exclude the occurrence of hydraulic shocks, stabilize and reduce the pressure in the water supply system; - reduce rushes and leaks of water; - increase the service life of equipment (hydraulic fittings and electrical equipment); 70 - to significantly minimize the costs of servicing the pumping station; - reduce the probability of emergency situations; - increase production safety.

The task is achieved by introducing a control cabinet containing a frequency converter for the main pumping unit, a soft start device for of the backup pump unit, the control panel and the control circuit, while the pressure sensor capable of forming a unified signal as a feedback signal for the control circuit to make a decision to start or stop the backup pump unit is placed on the outlet manifold.

The functional purpose of the set of distinguishing features is that in the automatic 2o mode of operation, the frequency converter controls the performance of the main pumping unit, maintaining the water pressure in the output collector. The feedback signal serves as the unified signal of the pressure sensor located on the output manifold, which is fed to the frequency converter. When the maximum performance of the main pumping unit is reached (maximum rotation frequency of the impeller of the pumping unit), the frequency converter sends a signal to the control circuit to perform a soft start of the reserve pumping unit using a soft start device. At the same time, the main pump unit continues to maintain the set pressure. When water consumption is reduced, the frequency converter reduces the performance of the main pumping unit. When the minimum performance of the main pumping unit is reached, the frequency converter sends a signal to the control circuit, after which it smoothly stops the backup pumping unit using a soft start device. Thus, this work algorithm allows to minimize the number of start-stop switches of the backup pump unit and significantly reduce the energy consumption of the entire system. i am

It is advisable to use this Ge system in manual operation mode under non-standard operating conditions or preventive works. At the same time, the main technological parameters are set manually using the control panel. Switching on the reserve pumping unit is also performed manually using the soft start device. with

In the event of an emergency, it is advisable to connect the pump unit directly to the power grid. In such cases, the protection of electric motors of the pumping station is carried out with the help of automatic switches and thermal relays. Transition to emergency system operation mode can be done either automatically or manually. "

The list of drawing figures from c The figures below explain the design features of the control system of the pumping station of the city water supply system, which is claimed. ;" Fig. 1 - general scheme of the automated control system of the pumping station of the city water supply system;

Fig. 2 - structural diagram of the control of the pumping station of the city water supply system; co Information that confirms the possibility of implementing a useful model

Pumping station 1 of the city water supply system includes two pumping units 2, Z, on each of which

Me, there are inlet valves 5 and outlet valves 4, water tank 5, outlet collector 6 with a pressure sensor 7 placed in it. The pumping station is connected to the water tank and directs water to consumers. The pumping station is connected to the power supply network 10. After the automation of the specified pumping station, it additionally includes a control cabinet 9, which includes a frequency converter 11, a soft start device 12, a control panel 13, a control circuit 14. A frequency converter 11 and a soft start device starter 12 are protected by fast-acting fuses ROI and RO2 (Fig-2). The frequency converter 11, the soft start device 12 and the control circuit 14 together make up the means of controlling the pump units 15. 5B The control system works as follows.

Before starting the system, the operating mode (automatic, manual or emergency) is selected from the control panel 13, the main pump unit 2, which works through the frequency converter 11, and the backup pump unit 3, which works through the soft start device. Switching inside the control cabinet 9 is performed using contactors K2-K5. The required pressure is set depending on the level of household activity of the population, because that lives in the area that is supplied with water from the same, and not, for example, an adjacent station. Since, based on the current level of household activity, it is possible to judge the dynamics of changing the population's need for water, and on the basis of these conclusions, it is possible to improve the quality of management of the performance of the pumping station.

The main operating mode of the system is the automatic mode. In the automatic mode of operation, the frequency converter 11 controls the performance of the main pump unit 2, maintaining the water pressure in the outlet 65 collector 6. As a feedback signal 8, the unified signal (4-20mA) of the pressure sensor 7 installed on the outlet collector b is used. The feedback signal is sent to the frequency converter 11. When the maximum performance of the main pump unit 2 (maximum rotation frequency of the impeller of the pump unit) is reached, the frequency converter 11 sends a signal to the control circuit 14. After a certain period of time, during which the signal about the maximum performance of the main pump unit 2 is confirmed, the control circuit 14 through the soft start device 12 performs the start-up of the backup pump unit 3. At the same time, the main pump unit 2, which is controlled by the frequency converter 11, continues to maintain the given technological parameter - the water pressure in the outlet collector 6. When consumption decreases of water, the frequency converter 11 reduces the performance of the main pump unit 2. When the minimum performance of the main pump unit 2 is reached, the frequency converter 11 sends a signal to the /o control circuit 14 and after a certain period of time, during which the signal about the minimum performance of the main pump of the unit 2 is confirmed, the control circuit 14 through the soft start device 12 stops the backup pump unit 3. When the productivity of the main pump unit 2 further decreases and the minimum level is reached, the control circuit 14 switches the frequency converter 11 to sleep mode.

Thus, this algorithm of operation of the automated system allows to reduce to a minimum the number of 7/5 start-stop inclusions of the reserve pumping unit Z and to significantly reduce the energy consumption of the entire pumping station.

When the system is operating in manual mode, for example, in the event of non-standard operating conditions, preventive work, all actions are performed manually by the operator: from the control panel 13, he sets the pressure value in the output manifold b, turns on and off the reserve pump unit 3. In this mode, the inclusion of 2 o reserve pump unit unit C is also performed through the soft start device 12, and the protection of the electric motors of the pump units is maintained.

In the event of emergency situations, the automated system automatically switches the pumping station into emergency operation mode and allows you to connect the pumping units directly to the power supply network, while using automatic switches АВИ1, АВ2 and thermal relays (not shown in Fig. 2)

Protection of electric motors of pumping units.

Thus, due to the fact that the proposed system uses a soft start device for o, a backup pumping unit, a frequency converter to control the operation of the main pumping unit, protection of the electric motors of the pumping units in any mode of operation, the above-mentioned technical result is achieved, which leads to increasing the efficiency of the city's water supply system. with you

Claims (2)

Formula of the invention (Se) 1. The automated control system of the pumping station of the city water supply system, which includes a pressure sensor, a pressure regulator and a switching unit, which is distinguished by the fact that it includes a control cabinet that contains a frequency converter for the main pumping unit, a soft start device for the backup of the pump unit, the control panel and the control circuit, while the pressure sensor capable of forming a unified signal as a feedback signal for the control circuit to decide whether to start or stop the backup pump unit is placed on the outlet manifold. " 2. The system according to claim 1, which differs in that it has the ability to work in automatic mode and/or with manual mode and/or emergency mode. ;" ime) (22) (22) s 50 IR e) s 60 b5