RU2508603C1 - Method and apparatus for forming aerosol projection screen - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: disclosed apparatus includes a means (100) for providing an aerosol designed to generate an aerosol stream (108) with average particle diameter of the disperse phase of less than 10 mcm in a screen formation area, a means (200) of providing a protective air stream designed to generate a protective air stream (210, 211) on two sides of the aerosol stream (108), wherein the aerosol stream (108) and the protective air stream (210, 211) have a non-laminar, locally turbulent flow near an obstacle on the flow path, wherein the Reynolds number for said streams near outlet openings (134, 215, 216) is in the range from 1300 to 3900.

EFFECT: improved method.

17 cl, 9 dwg

Description

FIELD OF THE INVENTION

The invention relates to a method and apparatus for forming an aerosol projection screen for creating physically permeable images, including in multimedia interactive displays.

State of the art

Known aerosol projection screens formed from an aerodispersed medium (aerosol), in particular, representing a planar cloud of fog supplied from the nozzles (exhaust channels) of the fog generator. An image is projected onto the formed flat surface of the screen from the side opposite to the observer. To reduce the dispersion of the cloud of fog as you move away from the exhaust channels, leading to a disruption in the planarity of the screen and a decrease in image quality, air curtains are created on both sides of the cloud of fog, parallel to the plane of the screen (US Pat. No. 5,270,752, publ. 12/14/1993), or a cloud fog is created inside the laminar transporting air stream (US Pat. US No. 6819487, publ. November 16, 2004), and at the farthest in relation to the outlet channels of the screen border there is a device for suction of the air-fog mixture, which allows additional stabilization acce screen.

The closest analogue of the claimed invention is the invention according to US Pat. US No. 6857746, publ. 02/22/2005, which proposed the formation of an aerosol projection screen by introducing an aerosol stream into a laminar transporting air stream.

A characteristic feature of existing technical solutions for the formation of an aerosol projection screen is the laminar nature of the flow of aerosol and transporting air, which allows you to limit the flow of material for the formation of the screen and provide acceptable optical uniformity of the screen, but adversely affects the stability of the screen during transverse movement of ambient air. The laminar nature of the flow of the aerosol also reduces the stability of the screen when introducing any objects into the screen area, which significantly limits the possibility of using such an aerosol screen in interactive control systems and information input. In addition, in these inventions, the plane of the aerosol screen is oriented vertically. This is partly a consequence of the design features, and partly due to the laminar nature of the aerosol flow. The inability to deviate the screen plane from the vertical is a drawback that significantly limits the possibility of use in electronic terminals, which, for ergonomic reasons, in most cases have tilted screens.

In addition, a known problem in existing devices for forming an aerosol projection screen is condensation or aggregation of the aerosol into large droplets on the walls of the exhaust channels, which prevents the aerosol from passing through the exhaust channels and leads to heterogeneity of the optical properties of the formed screen. When such a device is located above the formed screen, drops may fall down, which reduces the usability of the screen, especially in interactive control and information input systems where the user is in the immediate vicinity of the screen, and also leads to the need for absorbent carpets or other means to remove water under the screen. To prevent droplets from falling in patent application WO2010069368, publ. 06/24/2010, it is proposed to use a mobile device in which droplets formed from an aerosol stream are dried by an air stream, however, such a device has a complex structure and is applicable only in large-format displays.

Disclosure of invention

Structural and technological solutions used in the claimed invention, provide the formation of an aerosol projection screen designed to create physically permeable images and suitable for use in interactive control systems and input information.

A device for forming an aerosol projection screen comprises:

means for supplying an aerosol intended to create an aerosol stream with an average particle diameter of the dispersed phase of less than 10 μm in the screen formation zone, and

means for supplying a protective air stream designed to create a protective air stream from both sides of the aerosol stream,

in this case, the aerosol flow and the protective air flow have a non-laminar, locally turbulent nature of the flow near the obstacle in the flow path and the Reynolds numbers for the mentioned flows near the outlet openings are in the range from 1300 to 3900.

The aerosol flow rate and the protective air flow rate near the exhaust openings can be from 2 m / s to 6 m / s.

The width of the outlet of the aerosol stream can be from 1 to 5 mm.

The width of the protective air flow in the transverse direction on one side of the aerosol stream can be at least twice the width of the protective air flow in the transverse direction on the other side of the aerosol stream.

The outlet for the protective air flow may be provided with at least one cut-off element.

The outlet for the protective air stream may be provided on the side external to the aerosol stream with at least one deflecting element with an angle of inclination, variable in the range from 45 ° to 90 °.

The walls of the outlet channel of the aerosol stream may have a hydrophilic coating or may be made of a permeable material.

The aerosol stream may have a flat shape or a shape other than flat.

A device for forming an aerosol projection screen may include means for actively suppressing acoustic noise.

A device for forming an aerosol projection screen may include means for automatically controlling the aerosol flow rate and the protective air flow rate.

A device for forming an aerosol projection screen may include means for automatically controlling the aerosol flux density.

A device for forming an aerosol projection screen may comprise means for flavoring the air.

A device for forming an aerosol projection screen can be used in a multimedia interactive display, and control and input of information is carried out by introducing one or more fingers and / or one or more palms into the area of the aerosol projection screen.

Brief Description of the Drawings

FIG. 1 - display with an aerosol projection screen.

FIG. 2 - a device for forming an aerosol projection screen in cross section.

FIG. 3 - aerosol generator in cross section.

FIG. 4 - cutting elements.

FIG. 5 illustrates the use of a deflecting element to tilt the aerosol projection screen.

FIG. 6 - the use of two deflecting elements to provide a smaller thickness of the aerosol projection screen.

FIG. 7 - outlet openings.

FIG. 8 is a diagram of the formation of a boundary layer of aerosol flow.

FIG. 9 - dependence of the efficiency of light scattering on the ratio of the diameter of the aerosol particle to the light wavelength.

The implementation of the invention

The purpose of the invention is the formation of an aerosol projection screen designed to create physically permeable images, including in multimedia interactive displays.

In FIG. 1 shows a general view of a display with an aerosol projection screen. The display comprises a device (10) for forming an aerosol projection screen (40) in the form of a flat cloud of aerosol, the dispersed phase of which consists, for example, of drops (particles) of liquid, i.e. in the form of fog, and a projection device (30) for imaging on an aerosol projection screen.

In FIG. 2 is a cross-sectional view of an apparatus for forming an aerosol projection screen in one embodiment of the invention. A device (10) for forming an aerosol projection screen comprises means (100) for supplying an aerosol and means (200) for supplying a protective air stream. The means (200) for supplying a protective air flow comprises a housing (201) with side walls (204, 205) located along the plane of the formed screen, having upper parts (202, 203) and lower parts (204, 205), while the upper parts (202, 203) of the walls have a curved profile in the cross section of the device (10) and come closer to each other towards the upper surface (206) of the housing (201), in which an opening (207) is made for the release of the protective flow (210, 211) air. The aerosol supply means (100) is located in the housing (201) so that it forms channels (208, 209) with the inner surfaces of the upper parts (202, 203) of the walls of the housing (201) for supplying a protective air stream (210, 211) with exhaust holes (215, 216) in the opening (207) of the upper surface (206) formed between the aerosol discharge channel (107) and the outer side (217) of the opening (207). One or more discharge fans (212) are located in the housing (201), which are designed to take air (213) from the surrounding space through at least one intake hole (214) in the housing (201) and supply it to the channels (208, 209).

The aerosol supply means (100) comprises an aerosol generator (101), a controller (102) and an air velocity sensor (103). The surrounding air (213) through at least one intake opening (214) enters the inside of the housing (201) and then into the aerosol generator (101). The medium (105) is supplied through the nozzles (104) to the aerosol generator (101) to form the aerosol. As such a medium, water can be used. The aerosol generator (101) creates a highly dispersed aerosol (106) (for example, “dry” water fog), which enters at a given speed through the exhaust channel (107), forming an aerosol stream (108).

Fans (212) through the air ducts in the form of channels (208, 209) supply air through the outlet openings (215, 216), forming on both sides of the aerosol stream (108) a protective air stream (210, 211) necessary to protect the stream (108) aerosol from "erosion" as you move away from the outlet (134) due to friction arising in the boundary layer between the aerosol stream (108) and the surrounding air, and due to the movement of the surrounding air (wind, draft). In various embodiments of the screen module, one or more axial, radial, or tangential fans are used as discharge fans (212). It is also possible to use a compressor to supply air.

In FIG. 3 shows the design of an aerosol generator (101). The housing (109) of the generator is made with longitudinal side walls (110, 111), passing in the upper part into inclined sections (112, 113) directed towards each other. Inclined sections (112, 113) together with the inner surfaces of the upper parts (202, 203) of the walls of the housing (201) form channels (208, 209) for the protective flow (210, 211) of air. Inside the generator housing (109) there is an aerosol formation chamber (114), the lower part of which is a reservoir (115) with different-height side walls (116, 117) and a bottom (118). A longitudinal side wall (119) of the chamber (114) is adjacent to the lower wall (117) of the tank, and the upper part of the chamber (114) is limited by the inclined section (112) of the generator housing (109). The chamber (114) is divided by an inclined partition (120) into two areas above the level (121) of the medium in the tank (115): the aerosol formation region (122) and the aerosol transport region (123), into which the lower part of the aerosol discharge channel (107) exits . The generator (101) sprays the medium (105) and mixes it with air to form an aerosol (106).

The nozzles (104) provide the medium (105) to the aerosol generator (101) from the medium providing means (not shown) and the excess medium is removed to maintain its optimal amount in the tank (115). The medium providing means is intended to provide the aerosol generator (101) with the medium (105) from which the aerosol is formed. In one of the embodiments of the invention, the means of providing the environment is a means for water treatment, connected to the water supply network and providing for the purification, softening and disinfection of water. In another embodiment of the invention, the means for providing the medium comprises a container containing the medium for operating the device for forming an aerosol projection screen without being connected to a water supply network. In yet another embodiment of the invention, the means for providing the medium comprises means for extracting moisture from the surrounding air. In this case, an additional function of the means for providing the environment is to control the humidity in the room in which the device is installed, and to maintain it at a level comfortable for a person. The technical solutions used in the means for providing the environment are known in the relevant field of technology and their description is omitted. The supply of medium (105) to the tank (115) is controlled by the controller (102) based on the signal from the sensor (124) of the medium level.

In one embodiment of the invention, ultrasonic generators (125) are used to generate highly dispersed aerosol, for example, water fog, creating a fog in the chamber (114) with an average droplet diameter of less than 10 microns. In a preferred embodiment of the invention, the operating frequency of the ultrasonic generators (125) is selected so as to provide aerosol formation with an average particle diameter of the dispersed phase in the range from 1 μm to 1.5 μm, which ensures the maximum visible light scattering coefficient when passing through the aerosol screen and, accordingly, the maximum brightness of the projected image. When using water as a medium (105) for aerosol formation, the operating frequency of ultrasonic generators (125) should be from 1.7 MHz to 10 MHz. The internal volume of the chamber (114) is divided by an inclined partition (120) with an inclination angle (α) into the aerosol formation region (122) and the aerosol transport region (123). The optimal angle α is determined experimentally and in one embodiment of the invention is approximately 10 °. When using ultrasonic generators (125) in the case (109) of the aerosol generator (101), on the inner side of the inclined section (112), in the region (122) of aerosol formation, a chipper (126) is installed above the partition (120), which is a plate of a special shape, which serves to prevent large drops of medium (105) from fountains arising in the region (122) above the ultrasonic generators (125) from entering the aerosol transport region (123). The surface shape of the chipper (126) is selected taking into account the requirement to reduce aerodynamic losses during aerosol movement inside the chamber (114).

Air is supplied to the area (122) of aerosol formation through the air duct (128) under pressure, with the final part (129) of the air duct directed toward the reservoir (115). The aerosol generator (101) may contain injection means, for example, one or more fans (127), to provide the required air pressure or use the pressure created by the fans (212).

From the generator (101), the aerosol is supplied to the area of formation of the aerosol screen (40) through the channel (107) of the aerosol release. The aerosol exhaust channel (107) is an elongated hollow thin-walled structure with an inlet (lower) part (130) and an output (upper) part (131) passing one into another in the region of the transition section (132), and the walls of the outlet part (131) form a slotted portion (133) of the aerosol exhaust channel, and the walls of the inlet part (130) below the transition section (132) are located at an angle (β) to each other, forming a portion of the aerosol exhaust channel (107), tapering from the edge of the wall of the inlet part (130) ) to the transition section (132), while the outlet (134) of the flow and aerosol comes into the zone of formation of an aerosol of the screen (40) and the input edge wall portion (130) located in the region (123) of aerosol transport. The angle β is determined by the ratio of the geometric dimensions of the structural elements of the generator (101). The inner surface of the aerosol discharge channel (107) has a coating of hydrophilic material (135), which serves to prevent the formation of large water droplets due to condensation of water vapor and aggregation of water aerosol particles. Large droplets, the size of which is commensurate with the width of the slotted portion (133) of the aerosol canal, can disrupt the aerosol in the slotted portion (133) of the aerosol canal and worsen the spatial and temporal uniformity of the flow of the aerosol (108) from the outlet (134). The shape of the inlet part (130) of the aerosol discharge channel (107) tapering upward ensures the drainage of water along the surface of the hydrophilic material (135) into the reservoir (115) under the action of gravity. This design of the aerosol discharge channel (107) provides the required parameters of the aerosol screen (40) in the range of aerosol flow rates (108) from 2 m / s to 6 m / s. In another embodiment of the invention, the aerosol discharge channel (107) is made of a porous permeable material, which allows water to form droplets from the walls of the slotted portion (133) of the aerosol release channel, and the water that is drained is dried from the outer surface of the aerosol release channel (107) by an air stream channels (208, 209) of the release of the protective air flow. In one embodiment of the invention, one of the walls of the inlet part (130) of the aerosol discharge channel (107) is the side wall (119) of the chamber (114).

Fans (127) through the air duct (128) pump air into the aerosol formation region (122), and from fountains arising above the ultrasonic generators (125), medium (105) enters the aerosol formation region (122), resulting in an aerosol further arriving in the area (123) transportation of the aerosol. Due to the partition (120) and the wall (136) of the inlet part (130) of the aerosol discharge channel (107) at the entrance to the aerosol transport region (123), the aerosol flow (106) hits the surface (121) of the medium so that it reaches the region (123) ) aerosol transportation comes mainly aerosol with an average particle diameter of the dispersed phase of less than 10 microns. From the region (123) of aerosol transportation, a homogeneous finely dispersed aerosol (for example, “dry” water fog) passes through the aerosol discharge channel (107) and enters at a given speed through the outlet (134) with a width of no more than 5 mm to the area of formation of the aerosol screen (40 ) Aerosol (106) can be formed from a medium (105) other than water. The choice of medium (105) is determined by the conditions of use of the aerosol projection screen (indoors, outdoors) and the image formation method (optical projection of visible light, projection of infrared, ultraviolet, coherent or incoherent radiation and other types of projection).

In addition to using the ultrasonic aerosol generator (nebulizer) described above in the present invention, it is possible to use a compression type aerosol generator (atomizer), as well as other types of aerosol generator, for example a condensation type aerosol generator or nozzle-based aerosol generator.

The design of the device (10) for forming an aerosol projection screen provides the ability to control the speed of the aerosol at the outlet of the outlet (134) and the concentration of particles of the dispersed phase in the aerosol by means of the controller (102) by changing the supply voltage or the control signal supplied to the fans (127) and ultrasonic generators (125). The control of these parameters allows you to optimize the projection properties of the aerosol screen (brightness, contrast and image stability) depending on the ambient light, indoor humidity and external influences, for example, on the speed of transverse movement of ambient air (wind, draft). In one embodiment of the invention, the device (10) for forming an aerosol projection screen comprises an air velocity sensor (103), in accordance with the signal of which the controller (102) controls the aerosol flow rate from the outlet (134) by controlling fans (127, 212) and the speed of the protective air stream (210, 211) from the outlet openings (215, 216) so that the deviation of the aerosol screen (40) from a predetermined position under the influence of horizontal air flows does not exceed a predetermined value (for example , 15 °). The air velocity sensor (103) can be mounted on the housing (201) or in any other suitable place and communicate with the controller (102) in a known wired or wireless manner.

Outlets (215, 216) from the side of the aerosol discharge channel (107) and from the outside (217) of the opening (207) can be equipped with shut-off elements (218), which are aerodynamic elements and provide stabilization of the protective flow (210, 211) air by reducing the impact of the horizontal component of the velocity of the captured ambient air flows when leaving the outlet (215, 216). In FIG. 4 shows one of the possible profile profiles of the cutting elements (218).

In one embodiment, the aerosol stream (108) is flat. In another embodiment, the aerosol stream (108) has a shape other than flat, for example, a portion of the wall of the hollow cylinder, the curvature of which corresponds to the curvature of the aerosol discharge opening (134). It is possible to implement another form of aerosol stream (108), determined by the needs of the user.

In one embodiment, the width of the protective air stream (210, 211) in the transverse direction on one side of the aerosol stream is at least twice the width of the protective air stream in the transverse direction on the other side of the aerosol stream. The smaller width of the protective air flow from the user’s side additionally reduces the trace in the image when any objects are introduced into the screen area and helps to achieve a compromise between the overall stability of the aerosol screen and its sensitivity to user movements when controlling and entering information in single-point mode (touchscreen), multi-point mode (multi-touch), as well as with gesture control.

In one embodiment of the invention, it is possible to deflect the protective air stream (210, 211) from the vertical by means of at least one deflecting element (219), which is introduced into the protective air stream (210, 211) from a side external to aerosol flow, as shown in FIG. 5. Deviation of the protective air stream (210, 211) from the vertical allows the projection aerosol screen (40) to be deflected, providing a given angle γ from 45 ° to 90 °, and also allows to reduce the thickness of the aerosol stream and increase its density, which contributes to improve image quality. The deflecting element (219) is an aerodynamic element, the design of which is well known in aerodynamics. In addition to the deflecting element (219), other well-known technical means can be used to deflect the protective flow (210, 211) of air from the vertical.

In one embodiment of the invention, it is possible to provide a tilt angle γ of the aerosol screen (40) in the range from 45 ° to 90 ° both towards the user and from the user, or to maintain its vertical orientation by at least two deflecting elements (219) located on both sides of the aerosol stream (108), as shown in FIG. 6. The use of two or more deflecting elements (219) while maintaining the vertical orientation of the aerosol screen (40) allows for an additional reduction in the thickness of the aerosol stream and an increase in its density, which helps to improve image quality.

The technical solutions described above make it possible to obtain a homogeneous aerosol stream (108) at the exit from the aerosol canal (107) with an average particle diameter of the dispersed phase of less than 10 μm, which provides high brightness, contrast and image stability with a relatively small thickness of the aerosol screen (approximately 5 mm ) and low consumption of the working medium (105).

In one embodiment, the means (200) for supplying a protective air stream comprises means for actively suppressing acoustic noise (not shown), designed to reduce the level of acoustic noise caused by the operation of fans and other mechanical parts of the device (10) for forming an aerosol projection screen . The means for actively suppressing acoustic noise consists of an acoustic sensor, means for processing a signal of an acoustic sensor and an acoustic emitter. The action of the means for actively suppressing acoustic noise is based on the emission of an acoustic signal, the amplitude, frequency and phase characteristics of which depend on the noise environment and provide a reduction in the level of a certain part of the spectral components of noise in a certain area of space. Means for actively suppressing acoustic noise can be integrated into the fan (212) or placed in the housing (201) in such a way as to reduce the noise level in the user's area of residence. Technical solutions used in a means for actively suppressing acoustic noise are known in the relevant field of technology and their description is omitted.

In one embodiment of the invention, the device (10) for forming an aerosol projection screen has a modular design that allows you to easily change the configuration of the device depending on the needs of users. For example, the basic equipment, which includes means (100) for supplying an aerosol and means (200) for supplying a protective air stream, can be expanded by adding means for actively suppressing acoustic noise, means for automatically controlling the speed of an aerosol stream, a protective air stream, and aerosol flow density and means for aromatization of air.

An important aspect of the present invention is the selection of the flow pattern (108) of the aerosol forming the aerosol screen (40) and the protective flow (210, 211) of the air. At low speeds (1 m / s and less) that are characteristic of devices of the current level of technology, a laminar flow is observed, which provides better uniformity of the aerosol screen compared to turbulent, and also allows to reduce the flow rate of the medium. However, in this case, the stability of the aerosol screen is largely violated by the transverse flows of external air (wind, draft). In addition, when an object, such as a finger or palm, is inserted into the plane of the aerosol screen (40), an area of aerodynamic shadow (the so-called track) with a noticeably lower density of the aerosol is formed above it, as a result of which the quality of the image projected onto this area of the aerosol screen deteriorates.

According to [1], the velocity u of a planar laminar vertical air stream flowing around an obstacle, whose width l is much smaller than the flow width, at a distance x horizontally and y vertically from the center of the obstacle can be found as

, $$u=u_0{\left[\text{one}-\text{0}\text{,5}\left(erf\frac{x+\text{0}\text{,5}l}{cy}-erf\frac{x-\text{0}\text{,5}l}{cy}\right)\right]}^{\frac{\text{one}}{\text{2}}}$$

,

(t - любая величина или функция), u₀ - скорость невозмущенного потока на большом расстоянии по горизонтали от центра препятствия, с - экспериментальный коэффициент, равный 0,082.where is the error function $$erft=\frac{\text{2}}{\sqrt{\pi }}{\displaystyle \underset{\text{0}}{\overset{t}{\int }}{e}^{-t^{\text{2}}}dt}$$

(t is any quantity or function), u ₀ is the velocity of the unperturbed flow at a large horizontal distance from the center of the obstacle, and s is the experimental coefficient equal to 0.082.

Using the above expression, you can find the height of the wake behind the obstacle: for x equal to 0, the value u is 0.5u ₀ at a height above the obstacle h equal to 8l, and the value u is 0.8u ₀ at a height above the obstacle h equal to 18l. Thus, with an obstacle width l = 2 cm (human finger), the image quality will be noticeably deteriorated in an area about 16 cm high and will become comparable with the image quality in the unperturbed part of the aerosol screen only at a height of about 40 cm above the obstacle. For this reason, the use of laminar flows to form an aerosol screen when implementing interactive user interaction with an aerosol screen, in which information is controlled and entered by introducing one or more fingers and / or one or more palms into the area of the aerosol screen, is very problematic.

The height of the track over an object introduced into the area of the aerosol screen can be significantly reduced due to local turbulence that occurs when an aerosol stream flows around an obstacle. It is known in aerodynamics that when a laminar gas stream flows around the cylinder, a turbulent wake forms at the Reynolds number Re ₁ > 2000, moreover, at Re ₁ > 3500 the size of the wake significantly decreases and the average flow velocity is practically compared with u ₀ at a distance of the order of two or three cylinder diameters from the cylinder axis [2, 3]. In this case, the Reynolds number is calculated as

, $${\mathrm{Re}}_{\mathrm{one}}=\frac{\rho u_{0}d}{\eta }$$

,

where ρ is the gas density, η is its dynamic viscosity, d is the cylinder diameter. Assuming that the shape of a human finger is close to cylindrical, it can be determined that a value of Re ₁ = 3500 with a cylinder diameter of 2 cm corresponds to the velocity of the unperturbed aerosol flow u ₀ ≈ 3 m / s. Thus, the velocity u _{ex of the} outflow of the aerosol stream and the protective air stream from the outlet openings must satisfy the condition

(м/с). $$u_{ex}>3$$

(m / s).

Obviously, for a larger obstacle (for example, palm), the velocity of the aerosol flow and the protective air flow should be higher. However, for practical reasons, it is advisable to limit it to a value of approximately 6 m / s.

, где d_h - гидродинамический диаметр щелевого участка (133), который для канала прямоугольного сечения размерами a × b₁ можно определить как $$d_h=\frac{2a{b}_1}{a+b_1}$$

, а при условии a >> b₁ - как d_h ≈ 2b₁. Для достижения наилучшего качества аэрозольного экрана, отсутствия размывающих изображение вихрей и пульсаций скорости потока аэрозоля необходимо, чтобы поток (108) аэрозоля в щелевом участке (133) был ламинарным, что имеет место при $$\mathrm{Re}<2300$$

; отсюда получаем ограничение на ширину канала:Another important aspect of the present invention is the selection of the width of the outlet (134) of the aerosol stream (Fig. 7). The width b _{1 of the} outlet (134) of the aerosol stream determines the thickness of the stream (108) of the aerosol and the nature of its flow, which largely determine the optical characteristics of the aerosol projection screen (40). The nature of the flow of the aerosol stream (108) in the slotted portion (133) of the aerosol discharge channel (107) is determined by the Reynolds number $${\mathrm{Re}}_2=\frac{\rho u{d}_h}{\eta }$$

, where d _h is the hydrodynamic diameter of the slot section (133), which for a rectangular channel with dimensions a × b ₁ can be defined as $$d_h=\frac{2a{b}_{\mathrm{one}}}{a+b_{\mathrm{one}}}$$

, and under the condition a >> b ₁ - as d _h ≈ 2b ₁ . To achieve the best quality of the aerosol screen, the absence of vortices that blur the image and pulsations of the aerosol flow velocity, it is necessary that the aerosol flow (108) in the slot section (133) be laminar, which occurs when $$\mathrm{Re}<2300$$

; from here we get the restriction on the channel width:

. $$b_{\mathrm{one}}\approx \frac{{\mathrm{<figure-callout\; id="2"\; label="d\; h"\; filenames="00000035.png"\; state="\{\{state\}\}">d\; </figure-callout>}}_h}{2}=\frac{{\mathrm{<figure-callout\; id="2"\; label="Re"\; filenames="00000035.png"\; state="\{\{state\}\}">Re</figure-callout>}}_2\mathrm{<figure-callout\; id="2"\; label="\eta "\; filenames="00000035.png"\; state="\{\{state\}\}">\eta </figure-callout>}}{2\rho u}\Rightarrow b_{\mathrm{one}}<\frac{1150\eta }{\rho u}$$

.

The greater the thickness of the aerosol stream (108), the more blurry the image appears from the point of view of the observer, which becomes especially noticeable near the edges of the screen. In this regard, the value of b ₁ should be the minimum possible. On the other hand, to ensure a homogeneous aerosol flow close to the laminar flow necessary to obtain a high-quality image, the field of the aerosol flow velocity vector at the outlet of the outlet (134) should be as uniform as possible. However, when b ₁ decreases due to the formation of a near-wall boundary layer near the walls of the longitudinal slit portion (133), the thickness of which (δ) increases in the direction from the beginning of the slot portion (133), the aerosol flow velocity profile (108) changes and the velocity distribution over the channel cross section becomes heterogeneous.

, откудаIn FIG. Figure 8 shows a diagram of the formation of a boundary layer during the movement of an aerosol stream in a rectangular channel. A homogeneous aerosol stream enters the channel and its speed throughout the cross section is the same. As the flow advances in the channel, the flow is inhibited at the surface of the channel with the formation of a boundary layer. The following sections of the channel can be distinguished: section I, called the input, in which along with an increasing boundary layer there is an unperturbed flow core; section II, called the section of the change in the velocity profile; and section II, called the stabilized flow section. Obviously, in order to ensure an aerosol flow that is as uniform as possible in velocity at the outlet of the outlet (134), the length of the slot section l ₁ in the direction of flow should be less than the length of section I, which requires the fulfillment of the condition b ₁ > 4δ _max , where δ _max is the thickness of the wall boundary layer at the outlet of the outlet (134), which according to [4] can be calculated as $${\delta }_{\max }=\sqrt{\frac{\eta l_{\mathrm{one}}}{\rho u}}$$

from where

. $$b_{\mathrm{one}}>\mathrm{four}\sqrt{\frac{\eta l_{\mathrm{one}}}{\rho u}}$$

.

Combining this condition with the condition obtained above, we can obtain a criterion that the width of the slot section (133) and the width of the outlet (134) of the aerosol outlet channel (107) equal to it should satisfy:

. (*) $$\mathrm{four}\sqrt{\frac{\eta l_{\mathrm{one}}}{\rho u}}<b_{\mathrm{one}}<\frac{1150\eta }{\rho u}$$

. (*)

For example, given that at a temperature of 25 ° С the density of air is ρ ≈ 1.18 kg / m ³ and the viscosity of air is η ≈ 1.84 · 10 ^-5 Pa · s, at u = 4 m / s and l ₁ = 20 mm, criterion (*) gives the following range of optimal values of b ₁ : 1.1 <b ₁ <4.5 (mm). In embodiments of the present invention, the optimum width (b ₁ ) of the outlet (134) of the aerosol stream is from 1 to 5 mm.

In aerodynamics, it is known that an air stream flowing into the environment from a rectangular hole of length a and width b (a> b) can be represented as consisting of three sections, namely, the initial section, the plane stream section, and the compact stream section. In the initial section, there is a jet core and the velocity in the center of the jet is equal to the outflow velocity. In the subsequent sections, the boundary layer of the jet thickens, consisting of entrained environmental particles and inhibited particles of the jet itself, which leads to “erosion of the jet”, i.e. to an increase in its cross-sectional area and the gradual disappearance of the jet core [1, 5].

Obviously, for the projection of the image, it is necessary to use the initial section, since it is in this area that the width and flow rate (108) of the aerosol onto which the image is projected remains almost unchanged. Therefore, the distance H from the outlet openings to the image boundary opposite to them should not be greater than the length of the initial section of the jet l ₂ , which is determined by the smaller side of the outlet and is equal to

, $${\mathrm{<figure-callout\; id="2"\; label="l"\; filenames="00000035.png"\; state="\{\{state\}\}">l</figure-callout>}}_2=\frac{b}{\sqrt{\pi }c}\approx 6.88b$$

,

where c is the experimental coefficient equal to 0.082 [1]. Thus, assuming l ₂ ≥ H, we can obtain the condition for the width of the outlet (134): b ≥ 0.145H. The total width (b) of the air stream containing the aerosol stream (108) and the protective air stream (210, 211) is

, $$b=b_{\mathrm{one}}+2{\mathrm{<figure-callout\; id="2"\; label="b"\; filenames="00000035.png"\; state="\{\{state\}\}">b</figure-callout>}}_2+2b_3$$

,

where b ₂ is the width of the outlet (215, 216), b ₃ is the wall thickness between the outlet (215, 216) and the outlet (134). Therefore, the width of the outlet (215, 216) of the protective air stream (210, 211) must satisfy the condition

. $${\mathrm{<figure-callout\; id="2"\; label="b"\; filenames="00000035.png"\; state="\{\{state\}\}">b</figure-callout>}}_2\ge \mathrm{0,0725}N-b_{\mathrm{one}}/2-b_3$$

.

For example, for H = 50 cm, b ₁ = 4 mm and b ₃ = 1 mm, the calculation gives a value of b ₂ ≥ 31 mm.

To ensure the laminar nature of the air flow and the uniformity of the air velocity field at the outlet of the outlet openings (215, 216), these openings must be separated by partitions (220), the distance between which satisfies the same criterion (*) as the width b _{1 of the} outlet ( 134) aerosol flow.

Another important aspect of the present invention is the choice of aerosol particle diameter and medium flow rate.

, где F - световой поток, прошедший сквозь экран без рассеяния. Из [6, 7] известно, что F подчиняется закону Бугера:The brightness of the image projected onto the aerosol screen depends on the luminous flux F ₀ incident on the screen from the projector and the fraction of the light intensity scattered when passing through the screen $$k_{scat}=(F_0-F)/F_0$$

where F is the light flux passing through the screen without scattering. From [6, 7] it is known that F obeys the Bouguer law:

, $$F=F_{0}e{}^{-{\gamma }_s{b}_{\mathrm{one}}}$$

,

where γ _s is the scattering coefficient, which for an aerosol consisting of dielectric spherical particles of diameter d and density ρ ₁ with mass concentration m can be found according to the expression

, $${\gamma }_s=\frac{3mQ{}_{sca\mathrm{<figure-callout\; id="2"\; label="t"\; filenames="00000035.png"\; state="\{\{state\}\}">t</figure-callout>}}}{2{\rho }_{\mathrm{one}}d}$$

,

. Зависимости $$Q_{scat}({\alpha }_s)$$

для аэрозолей с различными веществами диспергированной фазы могут быть найдены в литературе. В качестве примера на фиг. 9 показана зависимость $$Q_{scat}({\alpha }_s)$$

для водяного аэрозоля.where Q _scat is the scattering efficiency factor, which is a function of the dimensionless parameter α _s relating the wavelength of the incident light λ and the particle diameter: $${\alpha }_s=\pi d/\lambda$$

. Dependencies $$Q_{scat}({\alpha }_s)$$

for aerosols with various substances of the dispersed phase can be found in the literature. As an example in FIG. 9 shows the relationship $$Q_{scat}({\alpha }_s)$$

for water aerosol.

The volumetric flow rate V of the medium used to form the aerosol can be defined as

. (**) $$V=\frac{ma{b}_{\mathrm{one}}{u}_{ex}}{{\rho }_{\mathrm{one}}}=\frac{2d{\gamma }_{s}a{b}_{\mathrm{one}}{u}_{ex}}{3Q_{scat}}=-\frac{2da{u}_{ex}\ln (\mathrm{one}-k_{scat})}{3Q_{scat}}$$

. (**)

With a constant value of the light flux incident on the aerosol screen F _{0, the} brightness of the visible image increases with increasing k _scat . However, as follows from the expression (**), an increase in k _scat leads to an increase in the flow rate of the working medium V, which reduces the battery life of the projection device and can lead to undesirable consequences, for example, to an excessive increase in indoor air humidity.

As the experimental results show, an acceptable image brightness when using compact multimedia projectors on the market is achieved at k _scat ≈ 0.3 for darkened rooms and k _scat ≈ 0.5 for office rooms with illumination of about 500 lux. Under these conditions, the expression (**) allows you to calculate the corresponding flow rate of the working medium for a given width a of the aerosol screen, velocity u of the outflow and the diameter d of the particles of the aerosol.

For example, for a = 60 cm, u _ex = 4 m / s and d = 3 μm when using water as a medium, the calculation gives a flow rate of 9.3 · 10 ^-7 m ³ / s (3.3 l / h) for darkened rooms and 1.8 · 10 ^-6 m ³ / s (6.5 l / h) for lighted office premises.

путем выбора оптимального диаметра d_opt частиц аэрозоля. Минимальному расходу V_min рабочей среды соответствует максимальное значение отношения $$Q_{scat}/d$$

. Аппроксимировав зависимость $$Q_{scat}({\alpha }_s)$$

полиномом и исследовав на экстремум отношение $$Q_{scat}/d$$

, можно определить оптимальный диаметр частиц аэрозоля d_opt, при котором достигается минимальный расход рабочей среды.The expression (**) also allows you to minimize the consumption of the working environment for a given $$k_{scat}$$

by choosing the optimal diameter d _opt of aerosol particles. The minimum flow rate V _{min of the} working environment corresponds to the maximum value of the ratio $$Q_{scat}/d$$

. Approximating the dependence $$Q_{scat}({\alpha }_s)$$

polynomial and exploring the extremum ratio $$Q_{scat}/d$$

, it is possible to determine the optimal diameter of aerosol particles d _opt , at which the minimum flow rate of the working medium is achieved.

для которого показана на фиг. 9, максимальное значение отношения $$Q_{scat}/d$$

достигается при $$d_{opt}\approx \mathrm{4,8}\lambda /\pi$$

. Для длины волны λ = 0,555 мкм, соответствующей наибольшей чувствительности человеческого глаза, d_opt ≈ 0,84 мкм. Соответствующий минимальный расход рабочей среды (воды) V_min при a = 60 см и u = 4 м/с равен 1,6·10^-7 м³/с (0,58 л/час) для затемненных помещений и 3,0·10^-6 м³/с (1,1 л/час) для освещенных офисных помещений.For example, for water aerosol, the dependence $$Q_{scat}({\alpha }_s)$$

for which is shown in FIG. 9, the maximum ratio value $$Q_{scat}/d$$

achieved when $$d_{opt}\approx 4.8\lambda /\pi$$

. For a wavelength of λ = 0.555 μm, corresponding to the highest sensitivity of the human eye, d _opt ≈ 0.84 μm. The corresponding minimum flow rate of the working medium (water) V _min at a = 60 cm and u = 4 m / s is 1.6 · 10 ^-7 m ³ / s (0.58 l / h) for darkened rooms and 3.0 · 10 ^-6 m ³ / s (1.1 l / h) for lighted office premises.

In connection with the foregoing, in a preferred embodiment of the invention, the aerosol flow rate (108) and the protective air stream (210, 211) flow rate are calculated so as to ensure acceptable image quality with non-laminar, locally turbulent nature of the flow of the aerosol stream (108), which will be observed near any object, for example, a finger inserted into the area of the aerosol screen. The best image quality on an aerosol screen under interactive user interaction is achieved in practice at an aerosol flow rate (108) in the range of 2 m / s to 6 m / s. For the outlet geometry (134) used in the invention, the indicated speed range corresponds to the range of Reynolds numbers from 1300 to 3900. The mentioned velocities and geometry provide the effect of closing the aerosol stream (108) and restoring a high-quality image within 1-5 cm above the introduced object (finger, with a few fingers and even the palm), which is necessary for controlling and entering information in single-point mode (touchscreen), in multi-point mode (multitouch), as well as for gesture control.

The technical result achieved in the proposed device for forming an aerosol projection screen is to increase the stability of the aerosol screen during the transverse movement of ambient air and to reduce the trace in the image when any objects are introduced into the screen region by providing a locally turbulent nature of the flow of the aerosol stream near the obstacle the flow path, the use of shut-off elements and ensuring the width of the protective air flow in the transverse direction from the user I do not less than half the width of the protective air stream transversely from the aerosol stream, the opposite side of the user; the possibility of tilting the aerosol screen due to the use of deflecting elements; increasing the uniformity of the optical properties of the aerosol screen and preventing droplets from falling due to the use of a hydrophilic coating or permeable material of the aerosol discharge channel.

Additional advantages of the claimed invention are: the ability to automatically change the speed and density of the aerosol stream, as well as the speed of the protective air stream, depending on external conditions (ambient light, lateral speed of ambient air, room humidity and others), the possibility of aromatization of air with fast change of aromas depending on the reproduced multimedia content and control actions of users and the possibility of flexible change of con device configurations for forming an aerosol projection screen depending on the needs of the user.

The devices, means, elements and features described in the present invention can be combined in various embodiments, if they do not contradict each other. The embodiments of the present invention described above are provided for illustrative purposes only and are not intended to limit the scope of the present invention as defined by the claims. All reasonable modifications, upgrades and equivalent replacements in the design and principle of operation, performed within the essence of the present invention, are included in the scope of the present invention.

Non-Patent Sources

[1] Shepelev I.A. Aerodynamics of air flows indoors. M .: Stroyizdat, 1978, 144 pp.

[2] Girgidov A.D. Technical mechanics of liquid and gas. SPb .: Publishing house of SPbSTU, 1999, 395 p.

[3] Birkhoff G., Sarantonello E. Streams, tracks and caverns. M.: Mir, 1964, 467 p.

[4] Brekhovsky L.M., Goncharov V.V. Introduction to continuum mechanics. M .: Nauka, 1982, 337 p.

[5] Abramovich G.N. Theory of turbulent jets. M .: ECOLIT, 2011, 720 p.

[6] Green H., Lane V. Aerosols - Dust, Smoke and Fog. M .: Publishing house "Chemistry", 1972, 448 p.

[7] Raist P. Aerosols. Introduction to the theory. M .: Mir, 1987, 280 p.

Claims (17)

1. The device (10) for forming an aerosol projection screen containing
means (100) for supplying an aerosol intended to create an aerosol stream (108) with an average particle diameter of the dispersed phase of less than 10 μm in the screen formation zone, and
means (200) for supplying a protective air stream intended to create a protective air stream (210, 211) from two sides of the aerosol stream (108),
characterized in that the means (100) for supplying an aerosol and the means (200) for supplying a protective air stream are configured to respectively create a stream (108) of aerosol and a protective stream (210, 211) of air, the Reynolds numbers of which are near the outlet openings (134, 215, 216) range from 1300 to 3900. 2. A device (10) for forming an aerosol projection screen, comprising
means (100) for supplying an aerosol intended to create an aerosol stream (108) with an average particle diameter of the dispersed phase of less than 10 μm in the screen formation zone, and
means (200) for supplying a protective air stream intended to create a protective air stream (210, 211) from two sides of the aerosol stream (108),
characterized in that the means (100) for supplying an aerosol and the means (200) for supplying a protective air stream are configured to respectively create a stream (108) of aerosol and a protective stream (210, 211) of air, the speeds of which are near the outlet openings (134, 215 , 216) range from 2 m / s to 6 m / s. 3. A device (10) for forming an aerosol projection screen, comprising
means (100) for supplying an aerosol intended to create an aerosol stream (108) with an average particle diameter of the dispersed phase of less than 10 μm in the screen formation zone, and
means (200) for supplying a protective air stream intended to create a protective air stream (210, 211) from two sides of the aerosol stream (108),
characterized in that the means (100) for supplying an aerosol and the means (200) for supplying a protective air stream are configured to respectively create a stream (108) of aerosol and a protective stream (210, 211) of air, the Reynolds numbers of which are near the outlet openings (134, 215, 216) are in the range from 1300 to 3900 and the width (b ₁ ) of the outlet (134) of the aerosol stream is from 1 to 5 mm. 4. A device (10) for forming an aerosol projection screen, comprising
means (100) for supplying an aerosol intended to create an aerosol stream (108) with an average particle diameter of the dispersed phase of less than 10 μm in the screen formation zone, and
means (200) for supplying a protective air stream intended to create a protective air stream (210, 211) from two sides of the aerosol stream (108),
characterized in that the means (100) for supplying an aerosol and the means (200) for supplying a protective air stream are configured to respectively create a stream (108) of aerosol and a protective stream (210, 211) of air, the Reynolds numbers of which are near the outlet openings (134, 215, 216) are in the range from 1300 to 3900, and the means (200) for supplying a protective air stream is configured to create a protective air stream (210), the width of which in the transverse direction on one side of the aerosol stream is not less than twice the width of the protective poto ka (211) of air in the transverse direction on the other side of the aerosol stream (108). 5. A device (10) for forming an aerosol projection screen, comprising
means (100) for supplying an aerosol intended to create an aerosol stream (108) with an average particle diameter of the dispersed phase of less than 10 μm in the screen formation zone, and
means (200) for supplying a protective air stream intended to create a protective air stream (210, 211) from two sides of the aerosol stream (108),
characterized in that the means (100) for supplying an aerosol and the means (200) for supplying a protective air stream are configured to respectively create a stream (108) of aerosol and a protective stream (210, 211) of air, the Reynolds numbers of which are near the outlet openings (134, 215, 216) are in the range from 1300 to 3900, and the means (200) for supplying a protective air stream comprises at least one outlet (215, 216) provided with at least one cut-off element (218). 6. A device (10) for forming an aerosol projection screen, comprising
means (100) for supplying an aerosol intended to create an aerosol stream (108) with an average particle diameter of the dispersed phase of less than 10 μm in the screen formation zone, and
means (200) for supplying a protective air stream intended to create a protective air stream (210, 211) from two sides of the aerosol stream (108),
characterized in that the means (100) for supplying an aerosol and the means (200) for supplying a protective air stream are configured to respectively create a stream (108) of aerosol and a protective stream (210, 211) of air, the Reynolds numbers of which are near the outlet openings (134, 215, 216) are in the range from 1300 to 3900, and the means (200) for supplying a protective air stream contains at least one outlet (215, 216) provided with a side external to the aerosol stream (108) at least one deflecting element (219) with an angle (γ) of inclination a, variable in the range from 45 ° to 90 °. 7. A device (10) for forming an aerosol projection screen, comprising
means (100) for supplying an aerosol intended to create an aerosol stream (108) with an average particle diameter of the dispersed phase of less than 10 μm in the screen formation zone, and
means (200) for supplying a protective air stream intended to create a protective air stream (210, 211) from two sides of the aerosol stream (108),
characterized in that the means (100) for supplying an aerosol and the means (200) for supplying a protective air stream are configured to respectively create a stream (108) of aerosol and a protective stream (210, 211) of air, the Reynolds numbers of which are near the outlet openings (134, 215, 216) are in the range from 1300 to 3900, and the means (100) for supplying the aerosol contains an exhaust channel (107), the walls of which are coated with a hydrophilic material (135). 8. A device (10) for forming an aerosol projection screen, comprising
means (100) for supplying an aerosol intended to create an aerosol stream (108) with an average particle diameter of the dispersed phase of less than 10 μm in the screen formation zone, and
means (200) for supplying a protective air stream intended to create a protective air stream (210, 211) from two sides of the aerosol stream (108),
characterized in that the means (100) for supplying an aerosol and the means (200) for supplying a protective air stream are configured to respectively create a stream (108) of aerosol and a protective stream (210, 211) of air, the Reynolds numbers of which are near the outlet openings (134, 215, 216) are in the range from 1300 to 3900, and the means (100) for supplying the aerosol contains an exhaust channel (107), the walls of which are made of a permeable material. 9. A device (10) for forming an aerosol projection screen, comprising
means (100) for supplying an aerosol intended to create an aerosol stream (108) with an average particle diameter of the dispersed phase of less than 10 μm in the screen formation zone, and
means (200) for supplying a protective air stream intended to create a protective air stream (210, 211) from two sides of the aerosol stream (108),
characterized in that the means (100) for supplying an aerosol and the means (200) for supplying a protective air stream are configured to respectively create a stream (108) of aerosol and a protective stream (210, 211) of air, the Reynolds numbers of which are near the outlet openings (134, 215, 216) are in the range from 1300 to 3900, and the device (10) for forming an aerosol projection screen has a modular design. 10. A device (10) for forming an aerosol projection screen, comprising
means (100) for supplying an aerosol intended to create an aerosol stream (108) with an average particle diameter of the dispersed phase of less than 10 μm in the screen formation zone, and
means (200) for supplying a protective air stream intended to create a protective air stream (210, 211) from two sides of the aerosol stream (108),
characterized in that the means (100) for supplying an aerosol and the means (200) for supplying a protective air stream are configured to respectively create a stream (108) of aerosol and a protective stream (210, 211) of air, the Reynolds numbers of which are near the outlet openings (134, 215, 216) are in the range from 1300 to 3900, and the device (10) for forming the aerosol projection screen creates an aerosol stream (108) having a flat shape. 11. A device (10) for forming an aerosol projection screen, comprising
means (100) for supplying an aerosol intended to create an aerosol stream (108) with an average particle diameter of the dispersed phase of less than 10 μm in the screen formation zone, and
means (200) for supplying a protective air stream intended to create a protective air stream (210, 211) from two sides of the aerosol stream (108),
characterized in that the means (100) for supplying an aerosol and the means (200) for supplying a protective air stream are configured to respectively create a stream (108) of aerosol and a protective stream (210, 211) of air, the Reynolds numbers of which are near the outlet openings (134, 215, 216) are in the range from 1300 to 3900, and the device (10) for forming an aerosol projection screen creates an aerosol stream (108) having a shape other than flat. 12. A device (10) for forming an aerosol projection screen, comprising
means (100) for supplying an aerosol intended to create an aerosol stream (108) with an average particle diameter of the dispersed phase of less than 10 μm in the screen formation zone, and
means (200) for supplying a protective air stream intended to create a protective air stream (210, 211) from two sides of the aerosol stream (108),
characterized in that the means (100) for supplying an aerosol and the means (200) for supplying a protective air stream are configured to respectively create a stream (108) of aerosol and a protective stream (210, 211) of air, the Reynolds numbers of which are near the outlet openings (134, 215, 216) are in the range from 1300 to 3900, and the device (10) for forming an aerosol projection screen comprises means for actively suppressing acoustic noise. 13. A device (10) for forming an aerosol projection screen, comprising
means (100) for supplying an aerosol intended to create an aerosol stream (108) with an average particle diameter of the dispersed phase of less than 10 μm in the screen formation zone, and
means (200) for supplying a protective air stream intended to create a protective air stream (210, 211) from two sides of the aerosol stream (108),
characterized in that the means (100) for supplying an aerosol and the means (200) for supplying a protective air stream are configured to respectively create a stream (108) of aerosol and a protective stream (210, 211) of air, the Reynolds numbers of which are near the outlet openings (134, 215, 216) are in the range from 1300 to 3900, and the device (10) for forming an aerosol projection screen comprises means for automatically controlling the flow rate (108) of the aerosol and the protective flow rate (210, 211) of the air. 14. A device (10) for forming an aerosol projection screen, comprising
means (100) for supplying an aerosol intended to create an aerosol stream (108) with an average particle diameter of the dispersed phase of less than 10 μm in the screen formation zone, and
means (200) for supplying a protective air stream intended to create a protective air stream (210, 211) from two sides of the aerosol stream (108),
characterized in that the means (100) for supplying an aerosol and the means (200) for supplying a protective air stream are configured to respectively create a stream (108) of aerosol and a protective stream (210, 211) of air, the Reynolds numbers of which are near the outlet openings (134, 215, 216) are in the range from 1300 to 3900, and the device (10) for forming the aerosol projection screen comprises means for automatically controlling the density of the aerosol flux (108). 15. A device (10) for forming an aerosol projection screen, comprising
means (100) for supplying an aerosol intended to create an aerosol stream (108) with an average particle diameter of the dispersed phase of less than 10 μm in the screen formation zone, and
means (200) for supplying a protective air stream intended to create a protective air stream (210, 211) from two sides of the aerosol stream (108),
characterized in that the means (100) for supplying an aerosol and the means (200) for supplying a protective air stream are configured to respectively create a stream (108) of aerosol and a protective stream (210, 211) of air, the Reynolds numbers of which are near the outlet openings (134, 215, 216) are in the range from 1300 to 3900, and the device (10) for forming an aerosol projection screen comprises means for flavoring the air. 16. The use of the device (10), characterized in any one of paragraphs. 1-15, in a multimedia interactive display, wherein control and input of information is carried out by introducing at least one control element from the group consisting of a human finger and a human palm into the area of the aerosol projection screen (40). 17. A method of forming an aerosol projection screen, comprising the following steps:
form an aerosol (106) from the medium (105),
create an aerosol stream (108) in the screen forming zone,
create a protective stream (210, 211) of air from two sides of the stream (108) of the aerosol,
and characterized in that it is implemented by a device (10) for forming an aerosol projection screen, characterized in any one of paragraphs. 1-15.

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