RU2520457C1 - Automatic device for fluid withdrawal - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: hopper is attached to a movable frame able of travelling in relation to a stationary frame with the help of an electric drive with a screw mechanism for the movement of the hopper movable frame. The device is fitted by a sensor, an automatic control unit for the electric drive with screw mechanism providing for the adjustment of the depth and immersion time of the hopper, monitoring of the hopper position in respect to the water level and monitoring of the turbidity of the withdrawn water. The automatic control unit for the electric drive with screw mechanism for the movement of the hopper movable frame comprises a data comparison unit, a timer, a travel algorithm execution unit.

EFFECT: possibility to automate the process of collection and withdrawal of coming to the surface and floating substances, provision for the possibility to control the amount of withdrawn water in wide range.

2 cl, 3 dwg

Description

The improvement relates to wastewater treatment plants, in particular biological wastewater treatment, and can be used to collect and discharge pop-up substances from the water surface in primary sumps, for example, to remove fat from the water surface; in SBR reactors (English SBR - Sequence Batch Reactor, variable reactor) for uniform discharge of a certain flow rate of treated water with constant monitoring of hopper movement; in averagers with a variable water level - for uniform water drainage with constant monitoring of hopper movement; in sludge thickeners - for drainage of clarified water with control of turbidity of water at the hopper overflow.

An automatic device for draining liquid is known (see USSR Author's Certificate 821410, С02F 1/52, 1981), comprising an immersion hopper in a water tank, a grease tube, the inlet of which is connected to the outlet of the hopper.

In the known device for removing floating substances, during the movement of the farm, floating on the water surface of the radial sump substances are collected using a semi-submersible board, which drives up the surfaced substances into the hopper, which is forcibly flooded when approaching the farm with a semi-submersible board. The hopper again rises above the water surface of the sump when the semi-submersible board leaves the hopper. In a flooded state, the hopper is removed by draining floating substances into it together with water into the grease tube of the sump. The bunker is automatically flooded every time a farm with a semi-submersible board approaches it. At the same time, a large amount of water is discharged into the bunker along with floating substances, even when there is a small amount of surfaced substances on the water surface of the sump, which increases the load on the treatment plant.

The technical problem solved by this improvement is to increase the efficiency of removing floating substances from the water surface or draining clarified water, reducing water removal through the hopper together with remote floating substances, the ability to work in manual or automatic modes of the device according to a given process technology.

The specified technical result is achieved in that an automatic device for draining the liquid containing an immersion hopper, a pipe whose inlet is connected to the outlet of the hopper, characterized in that the hopper is fixed to a movable frame, having the ability to move relative to a fixed frame using an electric drive mounted on it with the screw mechanism for moving the movable frame of the hopper, is equipped with at least one sensor, an automatic drive control unit with a screw mechanism for moving the movable Hopper frame, with adjustable depth and time spent under the bunker.

In an automatic device for draining liquid, the automatic drive automatic control unit with a screw mechanism for moving the moving frame of the hopper contains a data comparison unit, a timer, a stroke algorithm execution unit, where one of the inputs of the data comparison unit is connected to the timer output, the other of the inputs of the data comparison unit is connected to by the output of at least one sensor, the output of the data comparison unit is connected to the input of the execution block of the stroke algorithm, the output of which is connected to the input of the electric drive with ntovym mechanism for moving the movable hopper frame.

Technical result: the improvement allows to fully automate the process of removing floating substances through the hopper, to provide the ability to control and adjust the depth and time of the hopper under water, to monitor the position of the hopper relative to the water level, to provide control and adjustment over a wide range of the amount of water discharged through the hopper.

A specific example of the device is shown in the figures and diagrams.

Figure 1. Automatic device for draining fluid. Block diagram of a hopper moving electric drive control unit.

Figure 2. Automatic device for draining fluid. A fragment of the device.

Figure 3. Automatic device for draining fluid. A fragment of the device.

List of symbols in figures and diagrams

1. The reservoir.

2. The bunker.

3. Fat tube.

4. Movable frame.

5. Fixed frame.

6. Electric drive with screw mechanism.

7. The sensor.

8. Block of automatic control of electric drive 6.

9. Water level.

10. The lead screw.

11. Metal movable element.

An automatic device for draining liquid, hereinafter referred to as a device, is shown as an example of its use for collecting and draining pop-up substances from a water surface or draining clarified water from a tank.

The device is installed in a tank 1 with water, and contains a submersible hopper 2, a grease tube 3, the input of which is connected to the outlet of the hopper. The hopper 2 is fixed to the movable frame 4, which can be moved relative to the fixed frame 5 by means of an electric drive 6 mounted on it with a screw mechanism for moving the movable frame 4 of the hopper 2, equipped with at least one sensor 7, an automatic control unit 6 of the electric drive 6 with a screw the mechanism for moving the movable frame 4 of the hopper 2, with adjustment of the depth and time spent by the hopper 2 under the water level 9, with the ability to track the position of the hopper relative to the water level and the ability to control muddy STI diverted water.

The automatic drive control unit 8 with a screw mechanism for moving the movable frame 4 of the hopper 2 contains a data comparison unit, a timer, a stroke algorithm execution unit, where one of the inputs of the data comparison unit is connected to the timer output, the other of the inputs of the data comparison unit is connected to the output of at least one sensor 7, the output of the data comparison unit is connected to the input of the workflow algorithm execution unit, the output of which is connected to the input of the electric drive 6 with a screw mechanism for moving the movable we have 4 hopper 2.

The screw mechanism of the electric drive 6 contains a lead screw 10, fixed with its upper end to the shaft of the electric drive 6, and its other lower end to the movable frame 4 with a hopper 2 mounted on the movable frame 4.

The fixed frame 5 is equipped with a platform for maintenance of the electric drive 6 and control of the technical process of immersion under water level 9 and ascent above hopper 2 water level 9 in automatic or manual modes. To move the hopper 2, an electric drive 6 with a screw mechanism was used, for example, 250 W, 380 V. AUMA SA10.2 / F10, open / close position, complete with coupling type “A” DIN 3210.

As one of the sensors 7, an induction sensor is used that generates a clock pulse every time a metal element 11 passes through it, for example, a sludge scraper farm in the primary sump, or a metal element 11 of the float in the water tank 1 to monitor or maintain the required water level 9 in tank 1 (in the case of using the device in an SBR reactor of variable action, in the averager, thickener).

As another sensor 7, there may be a turbidity sensor of the discharged water through the hopper 2, or a level sensor for constant monitoring of the immersion depth of the hopper 2.

The middle part of the fat tube 3 is made of corrugated tube, from an elastic material, such as rubber or from a polymeric material such as impact-resistant PVC, and has the ability to bend when moving the hopper 2 above or below level 9 of water in the tank 1.

The upper end of the stainless steel grease tube 3 is rigidly and hermetically fixed to the hopper 2, the lower end of the grease tube passes through the wall of the tank 1.

In the tract of the grease tube 3, a pump can be installed for forced pumping of water from the tank 1 through the hopper 2.

The sensor 7 may be a turbidity meter for the discharge of clarified water, for example, in the case of using the device in a thickener.

The device operates as follows.

Two operating modes of the device are provided: manual or automatic, which are selected by the operator by switching the 2-position selector knob on the shield of the electric drive control unit 8 with a screw mechanism for moving the movable frame 4 of the hopper 2.

In manual mode, the immersion of the hopper 2 to a predetermined depth is determined by the duration of pressing the "down" button on the shield of the electric drive control unit 8. The maximum depth is set by the first limit switch of the electric drive 6.

The immersion time of the hopper 2 is visually controlled by the operator.

In the initial position, the upper part of the hopper 2 protrudes above the water level 9 by 25 mm or more, which can be adjusted by the operator on the shield of the unit 8 for automatic control of the electric drive 6.

Raising the upper part of the hopper 2 above the water level 9 in the tank 1 by pressing the "rise" button on the aforementioned shield of the automatic drive control unit 8, stop the electric drive 6 when the upper part of the hopper 2 is above the water level 9 in the tank 1 operation of the second limit switch of the electric drive 6.

In the automatic mode of operation of the device, the metal movable element 11 passes by the stationary sensor 7, then from the output of the sensor 7, a clock pulse is emitted every time a metal movable element 11 passes by it.

The clock pulse from the output of the stationary sensor 7 is fed to one of the inputs of the data comparison unit of the automatic control unit 8, which should also receive a control pulse from the timer, if the control signal does not go to any of the inputs of the data comparison unit, then the upper part of the hopper 2 above the level 9 of water in the tank 1, while the driving of floating substances into the hopper 2 does not occur, which increases their concentration on the water surface of the tank 1 and reduces the flow of water to remove floating substances from it.

Using the timer in the block of automatic control of the electric drive, the response frequency of the tap through the hopper 2 of floating substances is set. Upon receipt of a signal from block 8 of the automatic control of the electric drive to immerse hopper 2, then through the hopper 2 there is an intensive removal of floating substances, washing of the grease tube 3 and hopper 2 as a result of immersion of the hopper 2 below the level 9 of water in the tank 1 to a predetermined depth of its immersion.

The maximum depth of immersion or ascent of the hopper 2 is limited by the limit switches of the electric drive for moving the hopper 2, which are mounted on a fixed frame 5, where the electric drive 6 with a screw mechanism and a spindle 10 is installed.

The duration of the immersion of the hopper 2 is set according to the timer of the automatic control unit 8 and is an adjustable value.

The minimum volume of water discharged per bunker dipping cycle is 1.3-1.5 cubic meters.

If the control signal in the automatic control unit 8 from the timer is supplied to one of the inputs of the data comparison unit, then the output pulse of the data comparison unit receives a control pulse to the input of the execution block of the stroke algorithm, from which the corresponding control pulses arrive at the input of the electric drive 6, which screw 10 of the screw mechanism immerses the hopper 2 under the level 9 of water in the tank 1 or to a predetermined depth of immersion, holds the hopper 2 in the submerged position, moves the hopper 2 to its original position of the level of the water surface 9 of the tank 1.

In the flooded position of the hopper 2, the upper layer of water from under the water level 9 in the tank 1 is gravity drained into the hopper 2 together with floating substances that are discharged from the hopper 2 through the grease pipe 3 and enter, for example, again at the entrance of the treatment plant or to hell.

Block 8 of the automatic control of the electric drive has the following main functions: providing the possibility of manual and automatic modes of removal of floating substances from the water surface; automatic removal of floating substances during the day; equipment diagnostics according to specified algorithms; regulation of the technical process parameters - the frequency of operation of the device and the duration of the hopper in the flooded position; overload protection of electrical equipment; indication of the current and set parameters of the device; alarm system; equipped with manual control buttons on the shield of the wall cabinet with an electric drive control unit.

The height of the edge of the hopper 2 above the level 9 of water in the tank 1, in the limit of 20 ± 10 mm For example, in a specific example, 25 mm.

The immersion stroke of the hopper 2 is up to 180 mm, for example, in a specific example, 65 mm.

The hopper immersion cycle time is up to 20 s. For example, in a specific example, 10 s.

The duration of the hopper at a maximum depth of 1000 s, for example, in a specific example, 24 s.

The flow rate of the discharge of floating substances through the hopper is up to 200 l / s, for example, in a specific example, 48 l / s.

Water consumption for one bunker immersion is not more than 6 cubic meters.

Installation value from 1.3 to 1.5 cubic meters.

The rotation speed of the output screw 19 of the electric drive 90 rpm

When the hopper is deeply immersed from water level 9, when the hopper is completely filled with water to ensure maximum uniform water flow through hopper 2 or in the absence of floating substances, only water passes through hopper 2, which takes place in SBR reactors, averagers, thickeners.

Using the device allows you to:

- in primary settling tanks to fully automate the process of collecting and discharging pop-up and floating substances, to ensure the possibility of regulation over a wide range of the amount of discharged water and the amount of floating substances passing through the hopper;

- in SBR reactors to ensure uniform discharge of a certain flow rate of treated water with constant monitoring of the position of the hopper relative to the water level;

- in averagers with a variable level, ensure uniform water drainage with constant monitoring of the position of the hopper relative to the water level;

- in sludge thickeners, ensure clarified water discharge with constant monitoring of the position of the hopper relative to the water level with the control of turbidity, for example, at the overflow of a submerged hopper.

Claims (2)

1. An automatic device for draining the fluid containing an immersion hopper, a grease tube, the input of which is connected to the outlet of the hopper, characterized in that the hopper is fixed to a movable frame that can be moved relative to the fixed frame using an electric drive mounted on it with a screw moving mechanism the hopper frame, is equipped with at least one sensor, an automatic drive control unit with a screw mechanism for moving the moving frame of the hopper, with depth and time adjustment Meni silo under water. 2. The automatic device for draining the liquid according to claim 1, characterized in that the automatic drive control unit with a screw mechanism for moving the moving frame of the hopper contains a data comparison unit, a timer, a stroke algorithm execution unit, where one of the inputs of the data comparison unit is connected to the output timer, the other of the inputs of the data comparison unit is connected to the output of at least one sensor, the output of the data comparison unit is connected to the input of the block of execution of the stroke algorithm, the output of which is connected to about the input of the electric drive with a screw mechanism for moving the moving frame of the hopper.

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