RU141972U1 - SELF-CLEANING FILTER - Google Patents

Abstract

1. A self-cleaning filter including a supply and outlet pipe, a filter element, a device for cleaning it, a drive, a discharge line, characterized in that the filter element is made of perforated sheets arranged around the circumference of the sections, rigidly attached to the supply and / or outlet pipe, and the fact that the device for filter regeneration is made in the form of a rotor kinematically connected with the drive, installed in the supply pipe in front of the filter element, having an overlapping element that overlaps the filter part element, while the rotor is hollow, and its cavity is connected to the discharge line. 2. The self-cleaning filter according to claim 1, characterized in that the drive is made in the form of an electric motor. The self-cleaning filter according to claim 1, characterized in that the axis of rotation of the rotor coincides with the longitudinal axis of the supply pipe. The self-cleaning filter according to claim 1, characterized in that the individual sections of the filter element are made concave towards the outlet pipe. The self-cleaning filter according to claim 1, characterized in that the individual sections of the filter element are conical. The self-cleaning filter according to claim 1, characterized in that the individual sections of the filter element are made of stainless steel. The self-cleaning filter according to claim 2, characterized in that the electric motor is located outside the filter and is kinematically connected to the rotor of the regeneration device by means of a transmission shaft connected to the electric motor and an orthogonal gearbox connected to the rotor. The self-cleaning filter according to claim 1, characterized in that the overlapping rotor element of the hell regeneration device

Description

The technical field to which the utility model belongs.

The utility model relates to devices for filtering liquid media, namely, self-cleaning filters, including the supply and outlet pipes, a filter element, a device for cleaning it, a drive, a measuring and measuring device for measuring fluid flow and / or pressure drop in the supply and discharge pipes, which connected to the actuator switch with the possibility of turning it on and off according to a given flow rate or pressure drop across the filter, a discharge line in which the valve is installed with the possibility of communicating the internal cavity filter with a line reset when the drive and can be used for purification of liquids, such as sea water or other open reservoirs of solids that can be used for cooling the heat exchangers of nuclear power plants.

The level of technology.

A self-cleaning filter is known from the prior art, including a supply and a discharge pipe, a filter element, a device for cleaning it, a drive, a measuring and measuring device for measuring a fluid flow rate and / or a pressure drop in a supply and a discharge pipe, which is connected to the drive switch and can be turned on and shutdown according to a given flow rate or pressure drop across the filter, a discharge line in which the valve is installed with the possibility of communicating the internal cavity of the filter with a discharge line during operation of the actuator. See the description of the patent for the invention of the Russian Federation No. 2337745, published 10.11.2008.

This filter is the closest in technical essence and the achieved technical result to the proposed solution and is taken as a prototype of the proposed utility model.

Its disadvantage is that the filter element is cleaned by a direct liquid flow, so dirt particles stuck in the filter element are poorly removed. The absence of washing the filter element with a reverse flow does not make it possible to remove these clogged filter elements.

Disclosure of a utility model.

Based on this original observation, the present utility model mainly aims to propose a self-cleaning filter that allows at least to alleviate the above drawback, namely, to increase the cleaning efficiency of the filter element due to the possibility of cleaning the filter element with a reverse flow, while the filter does not work stops, and the flow direction of the filtered (cleaned) medium does not change, which significantly reduces the hydraulic resistance of the filter as a whole.

To achieve this, the filter element is made of circumferential sections of perforated sheets rigidly attached to the supply and / or outlet pipe. The device for filter regeneration is made in the form of a rotor kinematically connected with the drive, installed in the supply pipe in front of the filter element, having a blocking element overlapping part of the filter element, while the rotor is hollow, and its cavity is connected to the discharge line.

Due to such an advantageous characteristic, it becomes possible due to the overlapping of the filter element to provide a reverse fluid flow, which is able to detach dirt particles from the filter element, and it becomes possible to remove dirt particles from the filter element to a discharge line.

There is a variant of the utility model in which the drive is made in the form of an electric motor.

Thanks to such an advantageous characteristic, the filter makes it easier to manage, repair, and replace components and assemblies.

There is a variant of the utility model in which the axis of rotation of the rotor coincides with the longitudinal axis of the feed pipe.

Due to this advantageous characteristic, it becomes possible due to symmetry to ensure uniform distribution of solid particles over the filter element and, accordingly, to ensure uniform passage of the filtered medium without changing the direction of movement.

There is a variant of the utility model in which individual sections of the filter element are made concave towards the outlet pipe.

Due to this advantageous characteristic, it becomes possible to increase the amount of collected mechanical impurities without hindering the operation of the backwash rotor and the filter as a whole.

There is a variant of the utility model in which individual sections of the filter element are cone-shaped.

Due to this advantageous characteristic, it becomes possible to use the most optimal volumetric shape of the filter element sections.

There is a variant of the utility model in which individual sections of the filter element are made of stainless steel.

Thanks to this advantageous characteristic, it becomes possible to use a material that is both durable and corrosion resistant.

There is a variant of the utility model in which the electric motor is located outside the filter and is kinematically connected to the rotor of the regeneration device by means of a transmission shaft and an orthogonal gearbox.

Thanks to this advantageous characteristic, the time for replacing or repairing the motor and the filter as a whole is significantly reduced.

There is a variant of the utility model in which the overlapping element of the rotor of the regeneration device is adapted to overlap at least one section of the filter element.

Thanks to this advantageous characteristic, it becomes possible to optimize the operation of the self-cleaning filter.

There is a variant of the utility model in which the actuator switch is connected to a control device for measuring fluid flow and / or pressure drop in the supply and outlet pipes and is turned on and off by a predetermined flow rate of the liquid being cleaned or the pressure drop across the filter.

Thanks to this advantageous characteristic, it becomes possible to automate the on-off process of the filter self-cleaning mode.

There is a variant of the utility model in which the discharge line has a valve.

Due to such an advantageous characteristic, it becomes possible to block the discharge line and open it, in the open state to regulate the flow through it.

There is a variant of the utility model in which the discharge line is made in the form of a round pipe having a curved section adapted for connection with the rotor cavity, while the inner diameter of the cross section of the pipe of the discharge line is selected in the range of 0.1-0.3 of the internal diameter of the supply pipe.

Due to this advantageous characteristic, it becomes possible to optimize the aspect ratio of the parts of the self-cleaning filter and, as a result, to optimize the hydrodynamic regime.

There is a variant of the utility model in which the supply pipe and / or outlet pipe has at least one circular hole, closed by a lid, forming a process hatch.

Thanks to this advantageous characteristic, it becomes possible to provide access to the internal volume of the self-cleaning filter for repair and replacement of parts, for example, filter element sections.

There is a variant of the utility model in which the diameter of the round hole of the technological hatch is selected in the range of 0.4-0.6 of the inner diameter of the feed pipe.

Thanks to this advantageous characteristic, it becomes possible to optimize the aspect ratio of the parts of the self-cleaning filter and to reduce the time for filter maintenance.

There is a variant of the utility model in which the rotor blocking element is streamlined from the supply pipe side.

Due to this advantageous characteristic, it becomes possible to increase the flow rate of the reverse fluid flow, i.e. to exclude the flow of water through the gap between the rotor and the filter element.

The set of essential features of the proposed utility model is unknown from the prior art for devices of similar purpose, which allows us to conclude that the criterion of "novelty" for the utility model is met.

A brief description of the drawings.

Other distinguishing features and advantages of the utility model clearly follow from the description below for illustration and not being restrictive, with reference to the accompanying drawings, in which:

- figure 1 schematically depicts a functional diagram of a self-cleaning filter according to a utility model.

- figure 2 depicts an isometric view of a self-cleaning filter with a partial section according to a utility model.

- figure 3 depicts the sequence of stages of the self-cleaning filter according to the utility model.

According to figures 1 and 2, the self-cleaning filter includes a supply 1 and a discharge pipe 2, a filter element 3, a device 4 for cleaning it, a drive 5, a control device 6 for measuring fluid flow and / or pressure drop in the supply and discharge pipes, which is associated with a drive switch 7 with the possibility of turning it on and off according to a predetermined flow rate or pressure drop across the filter, a discharge line 8 in which the valve 81 is installed with the possibility of communicating the internal cavity of the filter with a reset line 8 during operation of the actuator 5.

The filter element 3 is made of circumferential sections 31 made of perforated sheets rigidly attached to the supply and / or outlet pipe 1 or 2. Separate sections are necessary to enable operation, backwashing and repair of the filter element, and the possibility of replacing individual sections.

The device 4 for filter regeneration is made in the form of a rotor 41 kinematically connected with the drive, installed in the supply pipe 1 in front of the filter element 3, having an overlapping element 42, overlapping part of the filter element 3, while the rotor is hollow, and its cavity is connected to the discharge line.

Mostly, the drive 5 is made in the form of a gearbox with an electric motor.

Mostly the axis of rotation of the rotor 41 coincides with the longitudinal axis of the feed pipe 1.

Advantageously, the individual sections of the filter element 31 are concave toward the outlet pipe.

Advantageously, the individual sections of the filter element 31 are conical.

Mostly the individual sections of the filter element 31 are made of stainless steel.

The electric motor is located outside the filter, and is kinematically connected with the rotor of the regeneration device via a transmission shaft 51 connected to the electric motor 5 and an orthogonal gearbox 52 connected to the rotor 41 by the axis 53.

The overlapping element of the rotor 42 of the regeneration device 4 is adapted to overlap at least one section of the filter element 31.

The actuator switch 7 is connected to the measuring instrument 6 for measuring the flow rate of the liquid and / or the pressure drop in the supply and outlet pipes and is turned on and off by a predetermined flow rate of the liquid being cleaned or the pressure drop across the filter.

The discharge line 8 has a valve 81, for the possibility of regulating the flow of discharged liquid. Regulation can be performed by the valve control device reset line 82.

Advantageously, the discharge line is made in the form of a round pipe having a bent section 83 adapted to be connected to the cavity of the rotor 41, while the inner diameter of the cross section of the pipe of the discharge line is selected in the range 0.1-0.3 of the internal diameter of the supply pipe.

The feed pipe 1 and / or the discharge pipe 2 has at least one circular hole 9, closed by a cover 91, forming a process hatch.

The diameter of the round hole 9 of the technological hatch is selected in the range of 0.4-0.6 from the inner diameter of the supply pipe 1.

The overlapping element of the rotor 42 is made streamlined from the side of the supply pipe 1.

The arrow in the figures shows the direction of water movement.

Outside of the supply and outlet pipes, legs 10 can be installed on which the filter is installed during operation.

Implementation of a utility model.

Self-cleaning filter works as follows. (See FIG. 3).

There are two modes of operation of a self-cleaning filter:

- liquid purification mode;

- self-cleaning filter element while cleaning the liquid.

Stage A1. The crude liquid enters the intake pipe 1. Next, it passes through the filter element 3, is cleaned, and enters the discharge pipe 2.

Stage A2. In the liquid purification mode, a measuring device 6 for measuring the liquid flow rate and / or the pressure drop in the supply and discharge pipes registers the pressure drop across the filter element or the flow rate of the filtered liquid. No rotation occurs, the rotor does not spin. In this mode, the overlapping element 42, overlaps part of the filter element 3, mainly one section 31.

Stage A3. If the pressure drop exceeds the limit or the liquid flow drops below the limit, the measuring device generates a signal to the switch 7 of the actuator 5 and the switch of the valve actuator of the discharge line (if any), while the filter is switched on in the self-cleaning mode of the filter element, during which the filtering process continues.

Stage A4. In the self-cleaning mode, the rotor rotates, the filter element is cleaned with backwash and the wash water is discharged through the discharge line. The rotation from the drive through the transmission 51 is transmitted to the rotor of rotation 52 with a blocking element ..

When the valve is opened on the discharge line, a pressure differential is formed between the internal volume of the filter (overpressure) and the internal volume of the outlet pipe with a rotor and a blocking element (atmospheric pressure). Under the action of a pressure drop through the filter element sector, closed by a blocking element, a reverse fluid flow occurs, which effectively removes contaminants from the filter element through the blocking element of the rotor to the discharge line.

Stage A5. In order to avoid jamming of the rotor when a large fraction of particles or a foreign object gets into the gap between the overlapping rotor element and the filter element, with increasing moment on the shaft, it may be possible to automatically reverse the drive 5 of the rotor 41 with the subsequent restoration of the direction of rotation of the rotor 41.

The sequence of steps is exemplary and allows you to rearrange, add or perform some operations at the same time without losing the ability to provide all the functions of the self-cleaning filter.

Industrial applicability.

The proposed self-cleaning filter can be implemented by a specialist in practice and upon implementation ensures the fulfillment of the stated purpose. The possibility of being implemented by a specialist in practice follows from the fact that for each feature included in the formula of a utility model based on the description, a material equivalent is known, which allows us to conclude that the criterion of "industrial applicability" for the utility model is met.

In accordance with the proposed utility model, the applicant carried out design calculations of a self-cleaning filter.

Design calculations have shown that a self-cleaning filter can allow the following:

- to clean the filter element without stopping the main filtering process, which allows you to use the self-cleaning filter for its intended purpose continuously until maintenance or repair;

- the design of the self-cleaning filter ensures the integrity of the filter elements and internal mechanisms with a flow rate of the cleaned liquid up to 8800 m ³ / h;

- the possibility of periodic cleaning of the filter elements backwash during the filtering process, i.e. the ability to operate the filter in two modes, namely:

- filtration mode - continuous cleaning of the fluid stream with a nominal (working) flow rate from mechanical impurities that accumulate in the filter element sections, thereby increasing the resistance of the self-cleaning filter up to the maximum allowable;

- self-cleaning (flushing) mode - sequential cleaning of sections of filter elements from mechanical impurities by a partial reverse flow of the filtered liquid, which, together with the contaminants, is discharged through the flushing nozzle during the main flow filtration process;

During the filtering mode, it can be provided:

- putting the self-cleaning filter into self-cleaning mode when the maximum allowable pressure drop across the filter element is reached or when the flow rate of the filtered liquid is lower than necessary, that is, power is supplied to the rotor electric drive while the contaminated water discharge line is turned on through the flushing nozzle;

- withdrawal from the self-cleaning mode can be carried out after a certain time or after a certain number of revolutions of the rotor or upon reaching a predetermined pressure drop of the filter element or flow rate of the cleaned liquid, i.e. the power supply of the rotor electric drive is disconnected while the discharge line for contaminated water through the flushing pipe is closed.

- the ability to automatically reverse the rotor drive with increasing torque on the shaft when jamming with the subsequent restoration of the direction of rotation of the rotor;

Additionally, the proposed filter design can provide:

- stability and the possibility of fixing it on the foundation;

- cleaning fluid from mechanical impurities with a size of at least 2 mm;

- the possibility of repairing the internals without dismantling the filter from the system due to the presence of the technological hatch.

All this, ultimately, ensures the achievement of the technical result achieved - increasing the efficiency of cleaning the filter element during self-cleaning of the filter.

Thus, the proposed utility model can be effectively used for cleaning liquid media from mechanical impurities, for example, for cleaning seawater, which is used as a refrigerant in heat exchangers of nuclear power plants, from solid impurities.

Claims (14)

1. A self-cleaning filter including a supply and outlet pipe, a filter element, a device for cleaning it, a drive, a discharge line, characterized in that the filter element is made of perforated sheets arranged around the circumference of the sections, rigidly attached to the supply and / or outlet pipe, and the fact that the device for filter regeneration is made in the form of a rotor kinematically connected with the drive, installed in the supply pipe in front of the filter element, having an overlapping element that overlaps the filter part element, while the rotor is hollow, and its cavity is connected to the discharge line. 2. The self-cleaning filter according to claim 1, characterized in that the drive is made in the form of an electric motor. 3. The self-cleaning filter according to claim 1, characterized in that the axis of rotation of the rotor coincides with the longitudinal axis of the feed pipe. 4. The self-cleaning filter according to claim 1, characterized in that the individual sections of the filter element are made concave towards the outlet pipe. 5. The self-cleaning filter according to claim 1, characterized in that the individual sections of the filter element are conical. 6. The self-cleaning filter according to claim 1, characterized in that the individual sections of the filter element are made of stainless steel. 7. The self-cleaning filter according to claim 2, characterized in that the electric motor is located outside the filter and is kinematically connected to the rotor of the regeneration device by means of a transmission shaft connected to the electric motor and an orthogonal gearbox connected to the rotor. 8. The self-cleaning filter according to claim 1, characterized in that the overlapping element of the rotor of the regeneration device is adapted to block at least one section of the filter element. 9. The self-cleaning filter according to claim 1, characterized in that the drive switch is connected to a control device for measuring fluid flow and / or pressure drop in the supply and discharge pipes and is turned on and off by a predetermined flow rate of the cleaned liquid or pressure drop across the filter . 10. The self-cleaning filter according to claim 1, characterized in that the discharge line has a valve for controlling the flow of discharged liquid. 11. The self-cleaning filter according to claim 1, characterized in that the discharge line is made in the form of a round pipe having a bent section adapted for connection with the rotor cavity, while the inner diameter of the cross section of the pipe of the discharge line is selected in the range of 0.1-0, 3 internal diameters of the feed pipe. 12. The self-cleaning filter according to claim 1, characterized in that the supply pipe and / or outlet pipe has at least one circular hole, closed by a lid, forming a process hatch. 13. The self-cleaning filter according to item 13, characterized in that the diameter of the round hole of the technological hatch is selected in the range of 0.4-0.6 of the inner diameter of the feed pipe. 14. The self-cleaning filter according to claim 1, characterized in that the overlapping rotor element is streamlined from the side of the supply pipe.

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