RU2228134C1 - Automatic vacuum cleaner with two liquid filters used for dry and wet cleaning of rooms - Google Patents

Abstract

FIELD: dust cleaning equipment used in tidying up of household and industrial rooms. SUBSTANCE: vacuum cleaner has body into which two liquid filters of primary and final purification of air are built. First filter is static, second is centrifugal interlocked with impeller of fan to from by that actuating mechanism generating balloelectric effect. Clear or opaque vessel for liquid is provided with branch pipe, comes in the form of body of revolution, which cylindrical wall has upper and lower flanges bent inwards and passing into two cylindrical surfaces. Upper flange is dipped into liquid with formation of static filter and lower flange with bottom bent in diametrical section passes into cone-shaped bottom of vessel. Sphere-shaped thin-walled shell dipped into vessel beneath wall of upper bent is attached to bottom of cover of upper part of body by means of several pillars, it carries level gauge and tube feeding liquid into device of wet cleaning of room. Ring-shaped inclined deflectors mounted on internal wall of body and on thin-walled shell ensure zigzag movement of air and impart vacuum cleaner with antibubbling and antioscillatory properties when moved. All above-mentioned parts and units have single vertical symmetry axis. Completion of vacuum cleaner with additional separable attachment ensures emptying of vessel during cleaning and on termination of room cleaning, level gauge indicates filling of liquid to required volume. EFFECT: given vacuum cleaner can operate as air cleaner under uninterrupted condition when connected to water main and wastewater disposal system or settling tank. 6 cl, 14 dwg

Description

The invention relates to dust collecting, floor, mobile (stationary) equipment and can be used in domestic and industrial conditions for the periodic cleaning of rooms and objects for various purposes, located in them, from dust and dirt. It can be periodically used for cleaning polluted air in domestic and industrial premises, and in the stationary version - as an air purifier operating in automatic continuous mode.

The first vacuum cleaner with a liquid filter was invented in the United States in 1932 [1]. Since then, products of this class have been constantly improved, since liquid filters installed in vacuum cleaners, compared to dry ones, have several advantages: a high degree of water purification with a relatively low resistance to air flow (higher efficiency), an economically and structurally more rational method of removal dust collected, lack of likelihood of allergies, etc.

At present, DELONGHI [2], AURA ROBOCLEAN [3] vacuum cleaners and other brands of vacuum cleaners are the most common and in demand on the home appliance market. The Nassreinigunggerat [4] also uses a static liquid filter.

The claimed vacuum cleaner has no analogues due to the fact that all known vacuum cleaners are not automatic vacuum cleaners with two liquid filters used for dry and wet cleaning.

Currently, in vacuum cleaners for thin air filtration, filters are widely used, the designation of which is “HEPA filters” (namely, High Efficiency Particulate Air), which are highly heat-resistant, permeable to hydrogen, oxygen, water vapor and CO ₂ , but retaining aerosols and solids from an inerting agent.

The objective of the invention is the creation of an automatic vacuum cleaner with two liquid filters used for dry and wet cleaning, and is expressed in the aggregate of essential features sufficient to achieve the technical result provided by the invention.

This result is achieved in that an automatic vacuum cleaner with two liquid filters used for dry and wet cleaning of the room is equipped with a flexible hose, a telescopic extension tube, a set of nozzles and a small diameter tube for supplying working fluid to the wet cleaning device and containing a lower case, which is a dust collector and having a plastic or metal base with or without rotating wheels and a transparent or opaque removable vessel for fluid made in the form of a body of revolution, the outer cylindrical wall of which has a C-shape, bent by the edges into the vessel, turning into two cylindrical or conical surfaces concentric with the outer wall, while the wall, which is a continuation of the upper bend, is lowered below the surface of the calculated level to be filled into a liquid vessel with the formation of a static filter for rough air purification, the wall of the lower bend smoothly passes into a conical horizontal bottom of the vessel with a bulge upward, and the bottom is lower its bend in a diametrical section is monotonically lowered downward with an increase in the height of the outer wall to a maximum value determining the installation location of the inclined cylindrical pipe, the axis of which passes simultaneously through two points, one of which is at or above the point of intersection of the surface level of the liquid poured into the vessel with the outer wall and the second point is the lowest point of the vessel located on the lower bend, and the pipe has a lock for connecting a flexible hose, while the vessel is hermetically connected along the perimeter of the junction with quick-release locks with the upper case having a handle, a control panel, a reversible electric motor with constant or variable power, mounted by the output shaft vertically downwards along the axis of symmetry and on shock absorbers on a round horizontal platform and in a thin-walled pipe fixed vertically in the cover of the upper case along its axis of symmetry and tapering upward with the formation of a seat for installing the HEPA filter and the output grating and with simultaneous bending with sufficient passage air with a gap of a thin-walled streamlined glass, which ensures the tightness of the drive compartment and the removal of thermal energy emitted during operation of the electric motor, while the glass is pressed by screws to a platform of equal or larger diameter to the glass and attached by rigid radial ribs evenly spaced along its circumference to the inner walls of the pipe to form a working the area of the annular grooves for air driven by an actuator, which is designed to provide suction power I and fine air filtration, is rigidly fixed to the output shaft of the electric motor with a guaranteed gap between the inner walls of the pipe vertically and the bottom of the transparent vessel horizontally and has an impeller with horizontal blades interlocked with a centrifugal liquid filter for fine air purification, with a vertical axis of symmetry consisting of two thin round sheets of dish-shaped or flat shape, the diameter of which is equal to or less than the inner diameter of the annular groove for air passage, while between the sheets vertical flat-shaped blades determining the distance between them are installed, directed radially or at an angle to the radius, or curved, or with the formation of a nozzle tapering to the outer diameter, and on the continuous top sheet having a conical streamlined protrusion with its top down, an adapter ring is installed that provides coaxial the filter is attached to the impeller from the bottom, and a cone-shaped pipe lowered into the liquid, the inner surface of which can be or has several screw-shaped grooves, while the lower part of the thin-walled pipe is configured to reflect the horizontal fluid flow incident on it at a given angle, or shortened in height to allow the flow to collide with an additional ring mounted on racks to the bottom of the upper housing cover, or with a ring on the inner wall of the housing, while all surfaces in contact with the liquid are smooth or ribbed to obtain a balloelectric effect, to the bottom of the cover of the upper housing on the racks coaxially with its vertical axis of symmetry, a sphere-shaped thin-walled shell is fixed, lowered by its wide part, for example, of a cylindrical shape, into a transparent vessel below the level of the inner wall of the upper bend and the centrifugal filter pipe, with the upper part of the pipe passing through an opening at the top of the shell having a gap relative to the nozzle and the bottom sheet of the filter, and on its inner side a level gauge with the possibility of automation of control is fixed, and the tube dropped below the calculated level aemoy in the liquid container to be connected to a device outside its wet cleaning or connected to a water mains pipe with integrated automatic valve means mounted on the cover of the upper housing fitting, with which it is sealed inside.

The actuator and the vessel with an inclined nozzle are located on the same vertical axis of symmetry, and the vacuum cleaner is equipped with an additional removable nozzle having a base fixed in the nozzle through which a composite tube passes, fixed in it so that its end is projected with a small gap into the lowest bending point the vessel, and the upper flexible part of the tube has a length sufficient for the possible discharge of the liquid available in the vessel into the sewer, and is equipped with a transition sleeve for attachment to the tap.

The actuator and the vessel with the inclined nozzle are located on the same vertical axis of symmetry, the vessel with the inclined nozzle is made in the form of a C-shaped body of revolution, the bottom of the lower bend of which is monotonically lowered in a diametrical section, while a tube connected from the inside is fixed to the inner side of the shell hermetically with a fitting mounted on the lid, the vessel has an additional vertical discharge pipe installed at its lowest point, to which a pipe with an integrated automatic upan with the possibility of draining the liquid through its second end into the sewer or into the sump, and the pipe fixed to the shell has the ability to connect through the fitting with a pipe with a valve to a water main or a pipe with a pump to a sump.

The actuator and the vessel with an inclined nozzle are located on the same vertical axis of symmetry, the shell is fixed coaxially with the axis of symmetry on the racks to the bottom of the top cover, and at least one additional one is installed on the inner wall of the upper case in a horizontal plane along the perimeter of the joint above the upper bend of the vessel sheet ring-shaped inclined reflector with an inner diameter smaller than the diameter of the bending wall and larger than the maximum diameter of the shell, on which at least one n a similar reflector with an outer diameter larger than the inner diameter of the reflector mounted on the inner wall of the upper case, while the reflectors overlap each other vertically with a guaranteed clearance to allow zigzag air movement.

The actuator and the vessel with an inclined nozzle are located on the same vertical axis of symmetry, below the ring on the inner wall there is an annular, trough-shaped cross section with the possibility of reflecting the filter water flow into it, while the channel has a vertical tube or tubes lowered into the vessel at the bottom.

List of drawings

Figure 1 shows the proposed vacuum cleaner, axonometric image.

Figure 2 shows the proposed vacuum cleaner, a section of a General view.

Figure 3 shows the proposed vacuum cleaner without wheels in a stationary embodiment, the shell with a wide part of a cylindrical shape.

Figure 4 shows an axonometric image of a vessel for liquid.

Figure 5 is a section aa in figure 2.

Figure 6 is a perspective view of a centrifugal liquid filter.

In Fig.7 is a section bB in Fig.2, the blades are rectilinear.

In Fig.8 is a section bB in Fig.2, the blades are curved.

Figure 9 is a section bB in figure 2, a tapering nozzle.

Figure 10 is a breakout in figure 3, shows a shortened pipe with an additional ring.

In Fig.11 - a pullout in Fig.3, shows a shortened pipe with a ring on the body.

On Fig - shows an additional removable nozzle.

On Fig - shows the installation of an additional removable nozzle.

On Fig - shows the installation of a gutter with tubes.

An automatic vacuum cleaner with two liquid filters, used for dry and wet cleaning of the room (shown in figures 1, 2 and 3), is equipped with a flexible hose 1, a telescopic extension tube, a set of nozzles and a small diameter tube for supplying working fluid to the wet cleaning device 2. It contains a lower case 3, which is a dust collector and has a plastic or metal base 4 with or without rotating wheels 5 and a transparent or opaque removable vessel for liquids inserted into the seat ty 6. The latter is made in the form of a body of revolution, the outer cylindrical wall of which 7 (see Fig. 4) has a C-shape bent by the edges inside the vessel, turning into two cylindrical or conical surfaces concentric with the outer wall, while the wall being the continuation of the upper bend 8, is lowered below the surface of the calculated level of liquid 9 poured into the vessel with the formation of a static filter. The wall of the lower bend 10 smoothly passes into the conical horizontal bottom of the vessel 11 with a bulge upward at an angle δ equal to 2-5 °. The bottom of the lower bend 10 in a diametrical section is monotonically lowered downward at an angle φ equal to 3-7 °, with an increase in the height of the outer wall 7 to a maximum value determining the installation location of the inclined cylindrical pipe 12. Its axis passes simultaneously through two points, one of which is located at or above the point of intersection of the surface level of the liquid 9 poured into the vessel with the outer wall 7, and the second point D is the lowest point of the vessel located on the lower bend 10 (see figure 2), and the pipe 12 has a lock for connection of a flexible hose 1. The vessel 6 is hermetically connected along the perimeter of the joint by quick-release locks 13 to the upper housing 14 due to the sealing gasket 15. The upper housing 14 with a handle 16 and a control panel 17 has a reversible electric motor 18 with constant or variable power, mounted by the output shaft vertically downward along the axis symmetry and shock absorbers on a circular horizontal platform 19 and in a thin-walled pipe 20. It is mounted vertically in the cover of the upper housing 21 along its axis of symmetry and tapers up to form a landing a space for the HEPA filter 22 and the output grating 23 and simultaneously encloses with sufficient air passage gap walled glass streamlined shape 24 which provides sealing cover 25 and drive dissipatable heat during operation of the motor. The glass is tightened by screws to the platform 19, equal to or larger than the diameter of the glass and attached by rigid radial ribs 26 evenly spaced around its circumference to the inner walls of the pipe 20 with the formation of the working area from the ring-shaped grooves for air 27 (see Fig. 5). The air is driven by an actuator 28, which is designed to provide suction power and fine air filtration, is rigidly fixed to the output shaft of the electric motor 18 with a guaranteed gap between the inner walls of the pipe 20 vertically and the bottom of the transparent or opaque vessel 11 horizontally. This mechanism has an impeller with horizontal blades 29, interlocked with a centrifugal liquid fine filter 30 (see figure 1), with a vertical axis of symmetry. This filter (see Fig. 6) consists of two thin round sheets of dish-shaped or flat shape 31 and 32, the diameter of which is equal to or less than the inner diameter of the annular groove 27 for air passage, while vertical flat-shaped blades determining the distance between them are installed between the sheets 33 directed radially or at an angle to the radius β (0 <β <90 °) (see Fig. 7), or a curved shape 34 (see Fig. 8), or with the formation of a nozzle tapering to the outer diameter 35 (cm Fig. 9). Moreover, on the continuous top sheet 31 having a conical streamlined protrusion with the top down 36, a transition ring 37 is installed that provides coaxial fastening of the filter to the impeller 29 from the bottom, and a cone-shaped pipe 38 lowered into the liquid is fixed to the hole and has a bottom sheet 32; the inner surface of which is smooth or It has several helical grooves. The lower part of the thin-walled pipe 20 is configured to reflect the horizontal fluid flow incident on it at a given angle α with the possibility of changing within 0≤α <90 ° (see Fig. 3) or shortened in height to allow the flow to collide with an additional ring 39 (see figure 10), mounted on racks 40 to the bottom of the cover of the upper housing 21, or with a ring 41 on the inner wall of the housing 14. All surfaces in contact with the liquid are made smooth or ribbed to obtain a balloelectric effect. A sphere-shaped thin-walled shell 42 (see FIGS. 2 and 3), lowered by its wide part, for example, of a cylindrical shape, into a transparent vessel 6 below the level of the inner wall of the upper bend 8 is fixed to the bottom of the cover of the upper case 21 on racks 40 coaxially with its vertical axis of symmetry and the nozzle of the centrifugal filter 38. Its upper part passes through an opening on the top of the shell 42, which has a gap relative to the nozzle and the bottom sheet of the filter 32. A level gauge 43 with the possibility of automation of control and a tube 44, lowered below the calculated level of the liquid 9 poured into the vessel with the possibility of connecting it externally to the wet cleaning device by the pipe 2 or connecting it to the water line by a pipe with an integrated automatic valve 45 using the fitting 46 mounted on the cover of the upper case to which it is hermetically connected from the inside .

The vacuum cleaner is equipped with an additional removable nozzle 47 (see Fig. 12), having a base 48, fixed in the inclined nozzle of the vessel 12 (see Fig. 13), through which passes a composite tube fixed in it so that its end 49 is projected with a small gap at the lowest bend point of the vessel D (see figure 2), and the upper flexible part of the tube 50 has a length sufficient to possibly drain the liquid 9 in the vessel into the sewer, and is equipped with a transition sleeve 51 for attachment to the tap.

In the stationary version of the manufacture of the vacuum cleaner (permissible without wheels) (see FIG. 3), its vessel with an inclined nozzle 6, the bottom of the lower bend 10 of which is monotonically lowered down, has an additional vertical drain pipe 52 installed at its lowest point. To it is connected a tube 53 with a built-in automatic valve with the possibility of draining the liquid through its second end into the sewer or into the sump, and the pipe 44 mounted on the shell has the ability to connect through the fitting 46 with a pipe with a valve 45 to the water main or pipes second with the pump 54 - to the sump.

At least one sheet ring-shaped inclined (angle γ equal to 2-5 °) reflector 55 (see figure 3) with an inner diameter is installed on the inner wall of the upper case 14 in a horizontal plane hermetically around the junction above the upper bend of the vessel 6 smaller than the diameter of the bending wall 8 and larger than the maximum diameter of the shell 42, on which at least one similar reflector 56 is fixed with an outer diameter larger than the inner diameter of the reflector 55 mounted on the inner wall of the upper case, and this reflectors 55 and 56 overlap each other vertically with a guaranteed gap to ensure the possibility of a zigzag motion of air and the possibility of damping the bubbling of liquid that occurs during operation of the fan, and its oscillations in the vessel 6 when moving the vacuum cleaner on the floor.

Below the ring on the inner wall of the housing 14 can be located ring, trough-shaped in cross-section groove 57 (see Fig. 14) with the possibility of reflecting the water flow of the filter into it, while the groove has a vertical tube or tubes 58 in the bottom, lowered into the vessel 6.

The device is used in two modes of operation: periodic, with movement on the floor, cleaning both the room itself and the objects inside it from dust and dirt, and without nozzles and a flexible hose - as an room air cleaner. In the second - stationary, continuous, automatic, with a constant connection to the water main and to the sewage system or sump, using the device only as an air purifier.

When working in the first mode, it is necessary to fix on the nozzle 12, equipped with a lock, a removable nozzle 47 and move the vacuum cleaner to the vessel or, conversely, bring the vessel to the vacuum cleaner. Pour liquid into the vessel, possibly pre-filtered, deodorized, with aromatic oils. When the nozzle 47 is installed, the end of the composite tube 49 is projected with a small gap into the lowest bend of the vessel of the vacuum cleaner 6. The upper flexible part of the tube 50 should be connected to the water tap using the adapter sleeve 51 or lower it into the vessel with the liquid filled. To prepare the vacuum cleaner for work, insert the electric cord into the power outlet with the plug 59 and press the "Liquid fill" button. In the first case, the impeller of the fan 29 is driven (possibly not at full power), and due to rarefaction, the liquid 9 is sucked into the vessel 6 in the volume limited by the level gauge 43, which gives the command to stop the motor 18, while being accompanied by light and sound signals indicating the end of the fluid in a predetermined volume in the vacuum cleaner. A simpler and cheaper solution: a calibrated volume of liquid (2.5, 3 l) is poured into the vessel, which is completely sucked through the tube 45 into the vacuum cleaner without using the level gauge 43. In the second case, the valve must be opened and the valve of the tube 45 automatically by the command of the level gauge 43 will block the flow of fluid into the vessel 6 of the vacuum cleaner.

To start working with a vacuum cleaner, it is necessary to replace the nozzle 47 with a flexible hose 1, to which the devices and nozzles traditional for vacuum cleaners should be connected (see figure 2). When the vacuum cleaner is turned on, the suction power causes the air, together with dust and dirt, to move from the nozzle through the telescopic tube, flexible hose 1, through the static filter for coarse cleaning of the vessel 6, the centrifugal fine filter 30, along the inner walls of the thin-walled pipe 20, HEPA filter 22 (installed if necessary, the finest air purification), grille 23 and again return already cleaned and moistened to the room. When wet cleaning, a wet cleaning device is attached to the flexible hose 1, and through the tube 2 it is connected to the nozzle 46, and by pump of this device, liquid is supplied through the tube from the vessel 6 to the rotating rollers, which first put clean liquid on the surface to be cleaned, and then collect it and with dust and dirt again sent to the vessel 6 through the hose 1. When using a vacuum cleaner as an air purifier, the principle of air purification itself does not change. The design feature of the vessel 6 is the following. The sucked-in dirty air is evenly distributed over the liquid 9 over the entire annular surface under the roof of the upper bend 8 and a rather small vacuum inside the vacuum cleaner is sufficient, for example, 0.05 atm with a wall immersion depth of 50 mm, so that the air overcomes a small adhesion force between the material from which a vessel 6 was made, and with liquid, it would first go down along the wall, while leaving large and medium particles of dirt at the bottom of the lower bend 10, and then round it, sharply up, creating a bubbling (bubble effect) at the exit and s liquid. Its intensity, proportional to the useful power of the fan, is suppressed by installing additional annular reflectors 55, 56 (see Fig. 3), about which the sprays, hitting, fly back down, and the air, having circled them, is sent further to the filter 30. The useful power a vacuum cleaner can be increased to a sufficient value, in contrast to a dynamic molecular separator [3], which limits this possibility. The second feature of the vessel 6 is the monotonous inclination of the bottom of the lower bend 10 towards the pipe 12 at an angle φ equal to 2-5 °, sufficient for automatic discharge of dirty liquid from the vessel. The conical pipe 38 of the filter 30 rotates and rotates the liquid 9 in the vessel 6, while simultaneously squeezing it to the bottom 11 due to its shape and, thus, plays the role of a centrifuge rotor, causing particles of dirt and dust to move as heavier fractions, to the inner surface of the wall 7 and to be located along its entire perimeter, simultaneously sinking down and settling on the bottom of the annular, inclined recess 10, where there is no rotation of the liquid. At the same time, the cleanest liquid 9 that accumulates in the center of the vessel 9 is sucked by the force of friction against the inner walls of the nozzle 38 and, having risen up, first falls onto the flat annular surface of the bottom sheet 32. Then it is evenly distributed by the conical protrusion 36 along the blades 33, 34 or nozzles 35 and, having dispersed along their working surface to a speed, the size of which depends on the configuration of the blades, overall dimensions of the round sheets of the filter 31, 32, the angle of the cone of the pipe 38, the number of revolutions of the output shaft of the electric motor 18, flies out of liter in the form of a continuous horizontal water stream formed at height 60. Requirements for this stream: it must have such a total kinetic energy that is sufficient not only to knock out the smallest particles of dust and dirt left in the air stream after the first rough filtration moving in the vertical direction from the bottom up (see FIGS. 2 and 3), but also to change their movement for a joint with the smallest particles of liquid in the horizontal direction. The final goal: either collision of the horizontal fluid flow 60 with the lower part of the pipe 20 at an angle α (see Fig. 3) while obtaining a balloelectric effect [6], or passing it outside the pipe before impacting with the ring 39 mounted on uprights 40, and in the absence of a ring, with a ring 41 on the inner wall of the upper casing 14. The essence of this effect is that when spraying and spraying water from mountain rivers and waterfalls as a result of the rupture of dipole molecules of water droplets, hydroions are formed, which, picked up, in our case, poto lump of air, can favorably affect the composition of indoor air. Depending on the class of the product and its cost, it is possible to improve the quality of fine filtration, but in any case, as the experiments showed, it is necessary that the linear velocity of each elementary particle of the liquid VΣ be no less than 25-30 times the speed of air movement, and consequently, dust and dirt particles, so that their energies differ by almost 5 • 10 ² times, conditionally assuming that the masses of the particles of liquid and dust are equal to each other. It is known that the kinetic energy W of any body with mass is

In fact, the filter 30 creates a kind of centrifugal "water sieve" in the air flow path of contaminated air, which it can entrain if the above conditions are met (the "Kriman effect"), and the parameters of which the device’s developer can calculate and optimize. Indeed, approximate calculations show the following. Suppose that the inner diameter of the pipe 20 is D = 0.2 m, the outer diameter of the round sheets 31, 32 of the filter 30 D ₁ = 0.14 m, the inner diameter of the flexible hose 1 D ₃ = 0.04 m, the number of revolutions of the output shaft of the electric motor n = 3000 rpm, the velocity of the sucked air through the hose 1, which actually determines the useful power of the vacuum cleaner, is assumed to be 5 m / s. Then the air velocity in the region of the filter 30 will be equal to 0.55 m / s, since its working area is 9 times larger than the flexible hose cross-sectional area, the fan capacity (intake air volume) is 22 m ³ / h, and the angular velocity ω is 10 ² π / s, the portable speed of the point M (see Fig. 8) V _e is 23.5 m / s, the relative speed V _r ~ 10 m / s. The absolute velocity of the fluid flow disengaging from the blades 34 will then be equal to the vector sum of its portable and relative velocities, ie ~ 40 m / s [7]. It is necessary that the direction of the absolute velocity vector coincides with the radius of the pipe 20 (see Fig. 8). By increasing the number of revolutions of the output shaft of the electric motor 18 to, for example, 15000-20000 rpm, it is possible, without changing the useful power of the vacuum cleaner, by reducing the angle of inclination of the impeller blades 29, to increase the level of air filtration or, conversely, to increase the useful power of the device, but slightly reduce filtration quality. With increasing suction power, it is possible to reduce the bubbling at the air outlet after the coarse filter by installing an additional annular inclined reflector (see figure 3). In this case, the liquid picked up by the air annular flow will be reflected from its surface downward, and the air, having circled it, will be directed towards the pipe 20 and the working area of the filter 30.

After cleaning the room from dust and dirt or during it, it is necessary to empty the vacuum cleaner vessel from contaminated liquid. In contrast to the known design solutions, the device under consideration allows this procedure to be carried out without disassembling the apparatus. To do this, it is necessary to replace the flexible hose 1 installed on the nozzle 12 with the nozzle 47 and lower its flexible tube 50 into the sewer. After pressing the "Liquid drain" button, the electric motor 18 (possibly not at full power) is turned on in the direction opposite to the working one, and, creating back pressure, thereby pushes all the liquid available in the vessel 6 into the sewer, which is facilitated by the inclination of the lower bottom ring the bend, causing it to move and concentrate at the lowest point of the vessel, over which with a small gap of not more than 5-7 mm, the rigid end of the tube 49 is placed. The procedure “Liquid filling” (see above) and “Liquid discharge”, if necessary repeat several lko times.

Known liquid vacuum cleaners that do not have an aroma called the “smell of a vacuum cleaner” are used in intermittent operation as air purifiers and room humidifiers, as indicated in their operational documentation. However, only the proposed device allows you to use it as an air purifier in continuous operation (see figure 3). For this purpose, the vessel 6 should be equipped with a drain pipe 52, the second end of which is lowered into the sewer or into the sump, through which the dirty liquid flows by gravity during periodic operation of the valve 61. At the same time, clean liquid to its corresponding volume in a vessel 6, controlled by a level gauge 43, is automatically, if necessary, supplied through a pipe with a valve 45 or a pump 54, one end of which is mounted on a fitting 46, and the other is connected to a water line (valve) or to a sump (water pump). The continuous operation of the device requires its stationary installation, so the presence of wheels in the base 4 is optional.

LITERATURE

1. US patent No. 1839582, cl. A 47 L 9/18, 1932

2. Prospect for the vacuum cleaner "DELONGHI".

3. Article "Dust Eaters". “Arguments and Facts”, No. 49, 2002.

4. European patent EP 0740922131, CL A 47 L 9/18, 05/05/1995 g.

5. European patent EP 1219223 A2, CL A 47 L 9/18, 12/25/2000

6. BME, ed. 3rd, t.2, "Aeroionization". M .: Sovencyclopedia, 1975.

7. B.M. Yavorsky and A.A. Detlaf. Handbook of Physics. M., 1968.

Claims (6)

1. An automatic vacuum cleaner with two liquid filters, used for dry and wet cleaning, equipped with a flexible hose, telescopic extension tube, a set of nozzles and a small diameter tube for supplying working fluid to the wet cleaning device and containing a lower housing, which is a dust collector and has a plastic or a metal base with or without rotating wheels and inserted into the seat transparent or opaque removable vessel for liquid, made in the form body of revolution, the outer cylindrical wall of which has a C-shape, bent by the edges inside the vessel, turning into two cylindrical or cone-shaped surfaces concentric with the outer wall, while the wall, which is a continuation of the upper bend, is lowered below the surface of the calculated level of liquid poured into the vessel with the formation of a coarse air filter, the wall of the lower bend smoothly turns into a conical horizontal bottom of the vessel with a bulge upward, and the bottom of the lower bend is diametrically the cut is monotonically lowered downward with an increase in the height of the outer wall to a maximum value determining the installation location of the inclined cylindrical nozzle, the axis of which passes simultaneously through two points, one of which is at or above the point of intersection of the surface level of the liquid filled into the vessel with the outer wall, and the second point is the lowest point of the vessel located on the lower bend, and the pipe has a lock for connecting a flexible hose, while the vessel is hermetically connected around the perimeter of the joint removable locks with the upper case having a handle, a control panel, a reversible electric motor with constant or variable power, mounted by the output shaft down vertically along the axis of symmetry and on shock absorbers on a circular horizontal platform and in a thin-walled pipe mounted vertically in the cover of the upper case along its axis of symmetry and tapering upward with the formation of a seat for installing a HEPA filter and an output grate and with simultaneous bending with a thin-walled gap sufficient for air passage streamlined cups, ensuring the tightness of the drive compartment and the removal of thermal energy emitted during operation of the electric motor, while the cup is pressed by screws to a platform of equal or larger diameter cups and attached by rigid radial ribs evenly spaced around its circumference to the inner walls of the pipe to form a working area of ring-shaped grooves for air driven by an actuator, which is designed to provide suction power and fine air filtration, rigidly fixed to the output shaft of the electric motor with a guaranteed gap between the inner walls of the pipe vertically and the bottom of the transparent vessel horizontally and has an impeller with horizontal blades interlocked with a centrifugal liquid filter for fine air purification with a vertical axis of symmetry consisting of two thin round sheets of dish-shaped or flat forms, the diameter of which is equal to or less than the inner diameter of the annular groove for the passage of air, while defining the angle between them is vertical flat blades, directed radially or at an angle to the radius, or curvilinear, or with the formation of a nozzle tapering to the outer diameter, and on the continuous top sheet having a conical streamlined protrusion with its top down, an adapter ring is installed that provides coaxial fastening of the filter to the impeller from the bottom, and on the bottom sheet having a hole, a conical nozzle lowered into the liquid is fixed, the inner surface of which is smooth or has several screw heads grooves, while the lower part of the thin-walled pipe is made with the possibility of reflecting the incident horizontal fluid flow at a predetermined angle or shortened in height to allow flow to collide with an additional ring mounted on racks to the bottom of the cover of the upper case, or with a ring on the inner wall the case, all surfaces in contact with the liquid are smooth or ribbed to obtain a balloelectric effect, and to the bottom of the cover of the upper case on the racks coaxially with its vertical axis a sphere-shaped thin-walled shell fixed to its symmetry, lowered with its wide part into a transparent vessel below the level of the inner wall of the upper bend and the centrifugal filter nozzle, while the upper part of the nozzle passes through an opening at the top of the shell, which has a gap relative to the nozzle and the lower filter sheet, and on its inner side a level gauge with the possibility of automation of control and a tube lowered below the calculated level of the liquid poured into the vessel with the possibility of connecting it externally to the device are fixed Wet wet cleaning of the room or connection to the water main with a tube with a built-in automatic valve by means of a fitting installed on the cover of the upper case, with which it is hermetically connected from the inside. 2. The vacuum cleaner according to claim 1, in which the actuator and the vessel with an inclined nozzle are located on the same vertical axis of symmetry and which is equipped with an additional removable nozzle having a base fixed in the nozzle through which the composite tube passes, fixed in it so that its end projected with a small gap into the lowest point of the bend of the vessel, and the upper flexible part of the tube has a length sufficient to possibly drain the liquid in the vessel into the sewer, and is equipped with a transition sleeve for mounting to anu. 3. The vacuum cleaner according to claim 1, in which the actuator and the vessel with an inclined nozzle are located on the same vertical axis of symmetry, the bottom of the lower bend of the vessel with an inclined nozzle in a diametrical section is monotonically lowered downward, while on the inner side of the shell a pipe is connected, which is sealed from the inside with a fitting mounted on the lid, the vessel has an additional vertical drain pipe installed at its lowest point, to which a pipe with an integrated automatic valve with the possibility of draining bone through a second end thereof to the sewer or to the sump, and fixed to the sheath tube has a possibility to connect via the connection tube with a valve to a water pipe or a pipe with the pump - to the sump. 4. The vacuum cleaner according to claim 1, in which the actuator and the vessel with an inclined nozzle are located on the same vertical axis of symmetry, and at least one sheet ring-shaped inclined is additionally installed on the inner wall of the upper case in a horizontal plane hermetically around the junction above the upper bend of the vessel a reflector with an inner diameter smaller than the diameter of the bending wall and larger than the maximum diameter of the shell on which at least one similar reflector with an outer diameter is fixed, pain their internal diameter is installed on the upper inner wall of the reflector body, the reflectors overlap each other vertically with clearance to allow air flow zigzag. 5. The vacuum cleaner according to claim 1, in which the actuator and the vessel with an inclined nozzle are located on the same vertical axis of symmetry, the shell is fixed coaxially with the axis of symmetry on the racks to the bottom of the top cover, and an annular, trough-shaped trough section is located below the ring on the inner wall with the possibility of reflecting the water flow of the filter into it, while the trough has a vertical tube or tubes lowered into the vessel at the bottom. 6. The vacuum cleaner according to claim 1, in which the wide part of the shell lowered into a transparent vessel has a cylindrical shape.

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