RU2298914C2 - Apparatus for automatic controlling of water flow rate supplied by pump-and-power unit - Google Patents

Abstract

FIELD: agriculture, in particular, irrigation systems, more particular, controlling of water flows supplied into upstream of open irrigation system.

SUBSTANCE: apparatus has upper, lower and minimum level sensors made in the form of hermetic contacts mounted on floats, in upstream water-intake construction, within hollow sleeves cooperating with magnets immovably fixed on sleeves. Hermetic contact of upper level sensor is connected to power unit through time delay relay, receiving-transmitting unit connected to unit for controlling of electric engine of downstream pump-and-power unit, control unit for main electric hydraulic relay and in parallel with end switch mounted on hydraulic drive of locking apparatus engageable with stop positioned on hydraulic drive stem in upper position of pump. Hermetic contact of lower level sensor is connected to power unit through time delay relay, receiving-transmitting unit, unit for controlling electric engine of downstream pump-and-power unit, control unit of additional electric hydraulic relay and in parallel with second end switch also mounted on hydraulic drive of locking apparatus and engageable with said stop in lower position of pump. Hermetic contact of minimum level sensor is connected to power unit and unit for controlling electric engine of upstream pump-and-power unit.

EFFECT: increased efficiency by providing automatic controlling of water flow rate supplied to upstream of open irrigation system.

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Description

The invention relates to agriculture, namely to irrigation systems, and can be used to control the flow of water into the upper pool of an open irrigation system.

A device for eliminating pulsation phenomena is known, including a pump installed in a water intake chamber equipped with a bypass pipe connecting the outlet (pressure) pipe to the suction pipe tangentially (AS 156420, class A01G 25/09, analogue).

The disadvantage of this device is the lack of the ability to automatically control the flow of water when changing the mode of water consumption in the upper pool of an open irrigation system.

Another device is known for automatically maintaining pressure in a closed irrigation network, including a pump and power unit with a control unit, a suction pipe and pressure pipelines connected tangentially by-pass pipe through a hydraulic locking device, divided into upper and lower cavities by means of a piston fixed on the hydraulic actuator stem controlled by an electrohydraulic relay, through the time delay unit, a reed contact and a magnet mounted on the rod, control the operating and actuating units of the electrohydrorelay, an additional electrohydrorelay, the executive unit of which is connected to the upper cavity of the hydraulic actuator, while the executive unit of the main electrohydrorelay is connected to the lower cavity of the hydraulic actuator, and the control unit of the auxiliary electrohydrorelay is connected to the power source through the lower limit of the electric contact pressure gauge and time delay relay, which controls the main electrohydrorelay unit is connected to the power source through the upper limit of the contact manometer and a time delay relay, moreover, the electric contact pressure gauge is installed in the pressure pipe of the pump and power unit, in addition, the reed contact interacts with the magnet in the upper position of the shutter hydraulic actuator rod and is sequentially connected to the electric contact pressure gauge of the upper limit and the control unit of the pump and power unit.

The disadvantage of this device is the lack of the ability to automatically control the flow of water when changing the mode of water consumption in the upper pool of an open irrigation system.

The technical task of the invention is the automation of the process of regulating the flow of water into the upper pool of an open irrigation system.

This object is achieved by the fact that the device is equipped with sensors of the upper, lower and minimum levels, made in the form of reed contacts mounted on floats and placed in the upper pool of the water intake structure, inside hollow glasses interacting with magnets fixed to the glasses, while the reed contact the upper level sensor is connected to the power source through the time delay relay, the transmit-receive unit with the electric motor control unit of the lower pump unit a, the control unit of the main electrohydraulic relay and in parallel with the limit switch mounted on the hydraulic actuator of the shut-off element, interacting with the stop located on the hydraulic actuator rod, in the upper position of the piston, and the reed switch contact of the lower level sensor with the power source through the time delay relay, the transmission-reception unit , the control unit of the electric motor of the downstream pump and power unit, the control unit of the additional electrohydraulic relay and in parallel with the second limit switch installed also on the hydraulic actuator of the locking element and interacting with the stop in the lower position of the piston, in addition, the reed contact of the minimum level sensor is connected to the power source, the control unit of the electric motor of the upstream pump and power unit.

Thanks to the supply of the upper downstream sensors with upper and lower level sensors and their connection with the power supply via a time delay relay, the transmit-receive unit with the electric motor control unit of the lower downstream pump and power unit and the control units of the main and additional electrohydrorelay make it possible to control the water flow rate in the intake the construction of the upper pool, depending on the changing water intake, which is impossible to implement either in the analogue or in the prototype. In addition, the placement of level sensors in the upstream water intake structure will significantly increase the speed of the automation system by monitoring the level changes directly in the water intake structure and instantly transmitting a signal to change the supplied flow rate. This will allow creating an optimal water supply regime linked to water intake in the upper pool, which will significantly reduce energy costs for uninterrupted water supply of the objects with the necessary amount of water.

The implementation of level sensors in the form of reed contacts installed on the floats and located in the upper pool of the water intake structure, inside hollow glasses interacting with magnets fixed to the glasses, and the connection of the reed contact of the upper level sensor to the power source through a time delay relay, transmit-receive unit with the control unit of the electric motor of the downstream pump and power unit and the control unit of the main electrohydraulic relay, and the connection of the reed contact of the lower level sensor a power source through a time delay relay, a transmit-receive unit, an electric control unit for a downstream pump and power unit with an additional electrohydraulic relay control unit not only provides a set of distinctive features not known either in the analogue or in the prototype, but will also allow to acquire a new positive effect - automatic control of the flow rate of the pumping power unit by the level in the intake structure of the upper pool, while ensuring speed in operation and eliminating error spine arising from wave process from the wind on the water surface by placing sensors in hollow glasses.

Supply of the device with a limit switch mounted on the hydraulic actuator of the shut-off member interacting with the stop located on the hydraulic actuator rod in the lower position and communication of the limit switch in the upper position with the electric motor control unit of the downstream pump and power unit and the upper level sensor, as well as supplying the device with a second limit switch mounted on the hydraulic actuator of the locking element and interacting with the stop in the lower position of the piston and its connection with the electric motor control unit by the body of the downstream pump and power unit and the lower level sensor, it provides not only a shutdown of the pump and power unit electric motor in the absence of water intake in the upstream, but also a signal generation in the control unit and the inclusion of an additional pump and power unit in operation when there is insufficient water supply to one unit upstream. This distinguishing feature is also not known either in the analogue or in the prototype.

Providing the device with a minimum level sensor installed in the upper pool of the intake structure, and the connection of the reed contact with the power source, the control unit of the electric motor of the pump and power unit of the upper pool will allow the pump and power unit to be switched off when there is no water supply from the lower pool, which eliminates air intake and the occurrence of cavitation processes leading to equipment wear. These distinguishing features and the resulting positive effect is impossible neither in the analogue nor in the prototype.

The drawing shows a schematic diagram of the proposed device for automatically controlling the flow of water by the pump-power unit.

A device for automatically controlling the flow rate of water by the pump-power unit includes water intake structures of the upper 1 and lower 2 downstream with pumping-power units and control units 3, 4, suction 5 and pressure 6 pipelines of the downstream pump and power unit 2, connected by tangential-bypass 7 by a pipeline through a locking device 8 with a hydraulic actuator 9, divided into upper and lower cavities by means of a piston 10, mounted on the rod 11 of the hydraulic actuator 9, controlled by the main 12 and additional 13 electric hydraulic relays connected to the upper and lower cavities of the hydraulic actuator 9 and equipped with control units 14, 15, sensors of the upper 16, lower 17 and minimum 18 levels, made in the form of reed contacts 19, 20, 21 mounted on the floats 22, 23, 24 and placed in the upper pool 1 of the intake structure, inside the hollow glasses 25, 26, 27, interacting with magnets 28, 29, 30, fixedly mounted on the glasses 25, 26, 27, while the reed contact 19 of the upper level sensor 16 is connected to the power source via a relay time delay 31, the reception unit-p transmission 32 with a control unit 4 of the electric motor of the downstream pump and power unit 2, a control unit 14 of the main electrohydraulic relay 12 and in parallel with the limit switch 33 mounted on the hydraulic actuator 9 of the locking device 8, interacting with the stop 34 located on the rod 11 of the hydraulic actuator 9, in the upper the position of the piston 10, and the reed contact 20 of the lower level sensor 17 with a power source through a time delay relay 35, a transmit-receive unit 32, a control unit 4 of an electric motor of a downstream pump and power unit 2, unitary enterprise with a reporting unit 15 of an additional electrohydraulic relay 13 and in parallel with the second limit switch 36, also mounted on the hydraulic actuator 9 of the locking device 8 and interacting with the stop 34 in the lower position of the piston 10, in addition, the reed switch contact 21 of the minimum level sensor 18 is connected to the power source, control unit 3 the electric motor of the pump-power unit of the upper pool 1.

A device for automatically controlling the water supply by the pump-power unit operates as follows.

The rise of water in the intake structure of the upper pool 1 to the upper level triggers the sensor 16 of the upper level, which is caused by the movement of the float 22 with the reed contact 19 in the hollow cup 25 up and at the mark set by the magnet 28 (upper level), the reed contact 19 is closed. provides the issuance of a pulse through a time delay relay 31, issuing an intermittent (periodic) pulse to the transmit-receive unit 32, which in turn transmits it to the downstream control unit 4 2. The control unit 4 causes a pulse to be sent to the control unit 14 of the main electrohydraulic relay 12 to open the shut-off device 8 by means of a hydraulic actuator 9 and to connect the suction 5 and pressure 6 pipelines. This provides a partial discharge of the water flow from the pressure pipe 6 to the suction pipe 5, which reduces the flow rate to the intake structure of the upstream pool 1. In case of insufficient opening of the shut-off device 8 (decrease in consumption), the time relay 31 gives a second pulse to the transmit-receive unit 32, the control unit 4 and the control unit 14 of the main electrohydraulic relay 12, which provides a further opening of the shut-off device 8 and an even greater reduction in the flow rate of the downstream pump-power unit 2. Discre The opening of the locking device 8 is carried out until the level in the upper downstream of the intake structure 1 drops below the upper limit, or when the piston 10 with the rod 11 reaches the upper position, when the stop 34 placed on the rod 11 of the hydraulic actuator 9, acting on the limit switch 33, closes it. As a result, the impulse from the time relay 31 is supplied through the limit switch 33 to the control unit 4 of the downstream pumping unit 2, causing the electric motor of the downstream pumping unit 2 to stop. The water supply to the upper downstream of the intake structure 1 is stopped, which stops the level increase water in the upper pool.

The fall of water in the intake structure of the upstream pool 1 to the lower level triggers the sensor 17 of the lower level, which is caused by the movement of the float 23 with the reed contact 20 in the hollow glass 26 down and at the mark set by the magnet 29 (lower level), leads to the closure of the reed contact twenty.

This provides a pulse through a time relay 35, issuing an intermittent (periodic) pulse to the transmission receiving unit 32, which in turn transmits it to the downstream control unit 4.

The control unit 4 provides a pulse to the control unit 15 of the additional electrohydraulic relay 13 to close the shut-off device 8 by means of a hydraulic actuator 9. This reduces the partial discharge of water flow from the pressure pipe 6 to the suction pipe 5, which increases the flow rate to the water intake structure of the headwater 1. When insufficient closure of the shut-off device 8, the time relay 35 gives a second impulse until the shut-off device 8 is completely closed. In case of failure to ensure the rise of water in the intake m, the construction of the headwater 1, above the lower level, as a result of the action of the stop 34 in the lower position of the piston 10 (complete closure of the locking device 8) on the second limit switch 36 mounted on the hydraulic actuator 9 of the locking device 8, the circuit is closed and an impulse is issued to turn on the second pumping power unit.

The fall of water in the intake structure of the upper pool to the minimum level leads to the triggering of the sensor 18 of the minimum level, which is caused by the movement of the float 24 with the reed contact 21 in the hollow cup 27 down and at the mark (minimum level), the magnet 30 causes the reed contact 21 to be closed. pulse to the control unit 3 of the electric motor of the pump-power unit of the upper pool 1 to stop the electric motor.

The introduction of the proposed device for automatically controlling the flow of water by the pump and power unit on irrigation systems will reduce operating costs by 5-10%, reduce the energy consumption for water supply by 8-12% due to the creation of an optimal water supply mode, linked to the water intake structure of the headwater .

Claims (1)

A device for automatically controlling the flow rate of water by a pump and power unit, including the intake structures of the upper and lower pools with pump and power units and control units, the suction and pressure pipelines of the lower pool pump and power unit, connected by a tangential by-pass pipe through a shut-off device with a hydraulic actuator, divided on the upper and lower cavities by means of a piston mounted on the hydraulic actuator rod, controlled by the main and additional electrohydraulic relay, connected to the upper and lower cavities of the hydraulic actuator and equipped with control units, a time delay relay, a reed contact and a magnet, characterized in that the device is equipped with sensors of the upper, lower and minimum levels, made in the form of reed contacts installed on floats and located in the upstream water intake structures inside hollow glasses interacting with magnets fixed to the glasses, while the reed contact of the upper level sensor is connected to the power source through a relay e time delay, a transmit-receive unit with a control unit for the electric motor of the downstream pump and power unit, a control unit for the main electrohydraulic relay and, in parallel with the limit switch, mounted on the hydraulic actuator of the locking device, interacting with the stop located on the hydraulic actuator rod in the upper position of the piston, and reed switch contact of the lower level sensor with a power source through a time delay relay, a transmit-receive unit, a motor control unit of a lower pump and power unit downstream, controlling the unit of the additional electrohydraulic relay and in parallel with the second limit switch, also mounted on the hydraulic actuator of the locking device and interacting with the stop in the lower position of the piston, in addition, the reed switch contact of the minimum level sensor is connected to the power source, the control unit of the electric motor of the pump and power unit of the upstream downstream.