RU185630U1 - Flame and smoke simulator - Google Patents

Abstract

The inventive utility model relates to devices for electric fireplaces and, in particular, to a device simulating a flame when burning solid fuel and / or simulating smoke generated during burning of solid fuel.

The device consists of a housing, inside of which elements imitating solid fuel, for example firewood, are placed on the substrate 1. Light sources 3 are placed on the base of the housing under the underside 1. A groove 2 is made in the underlay 1 to allow air and steam to escape from the distribution and filling chamber 7 of the air mass. Inside the housing there is a container 4 filled with a liquid, for example water. At the inlet, the container 4 is equipped with an air duct 6, which allows the air mass to pass through the container 4 and the microcontainer 14, in communication with the chamber 7 of the distribution and filling of the air mass. The chamber 7 of the distribution and filling of the air mass is made of transparent plastic and is located under the substrate 1. The microcontainer 14 is hydraulically connected to the container 4, is equipped with a fan 8, which transports a directed air flow through the container 4 to the duct 6 through the microcontainer 14 to the filling and distribution chamber of the air mass 7. The cross-sectional area of the chamber 7 of the distribution and filling of the air mass has a cross-sectional area greater than the duct 6. The microcontainer 14 is filled with liquid from the container Era 4, ultrasonic evaporators 9 are immersed in the liquid, mounted on the bottom of the microcontainer 14 and electrically connected to a hygrostat and a hygrometer 10 to maintain a given humidity. At the inlet of the duct 6 in the container 4, an air filter 11 is installed, which cleans the incoming air mass from dust of other suspended particles. A filter 12 is placed in the container 4, preventing the formation of salt deposits on the walls of the container 4. The device is equipped with an aromatic capsule 13, flavoring the steam coming from ultrasonic emitters 9. The microcontainer 14 is heated to further treat the bacteria from bacteria if the device is not used for a long time. In the container 4 is placed a liquid level sensor 15. The device comprises a control unit connected to an electrical part, providing connection of light sources 3, fan 8, ultrasonic evaporators 9, a hygrostat and hygrometer 10, a liquid level sensor 15 with an external power source, and a control panel on the outside of the housing. The housing has a ventilation window for the natural circulation of air flow.

The technical result is an improvement in the quality of steam simulation while increasing the efficiency of the device, including by expanding the functionality by giving an additional function to humidify the air in the room in the process of controlled steam simulation of smoke. 7 c.p. crystals, 6 pic.

Description

The inventive utility model relates to devices for electric fireplaces and, in particular, to a device simulating a flame when burning solid fuel and / or simulating smoke generated by burning solid fuel.

There is a significant range of devices designed to simulate flames during the combustion of solid fuels (WO 02/099338, WO 97/41393). Devices may contain models of firewood or coal made of plastic, and illuminated from below by a variable intensity light source of red or orange, or may include imitation of a smoldering substrate also made of plastic, a metal grid and other models of elements of combustion or decay. The devices may include a display with a dynamic image of flames, or the optical effect of the flame can be created by projecting light onto a matte screen through current flows of colored liquid (EP 1703211) or through mutually moving optical elements (GB 2484734). Volumetric flames are also simulated by highlighting in red the jets of steam coming from the steam generator (GB 2498329, GB 2502077). Steam can be directed through different channels and highlighted in different colors (US20100299980). The presence of smoke in electric fireplaces is modeled using water vapor (GB 2391933, GB 2402206, GB 2460259, WO 03063664, US 20080028648). Water vapor can be formed by placing in a container with water a set of electrodes lowered into a liquid container and intended for its evaporation (RU 144155). The resulting vapor is directed up and highlighted, thus simulating smoke from burning fuel.

Currently, the most common devices for simulating smoke are devices where the vapor is formed by ultrasonic transducers. In particular, the design of the fireplace is known, including the main and additional reservoirs with liquid, an aerosol generator, light source (s), a fan, a substrate with a fuel simulator. The aerosol generator may include one or more ultrasonic transducers that can be controlled by a controller to control the volume of the resulting aerosol. Ultrasonic transducers can be mounted on the bottom of a liquid tank (US 8413358, 2009).

As noted in some patent documents, the main drawback of this fireplace design is the loss of steam to simulate smoke, as part of the formed vapor settles on a part of the surface of the substrate of the fuel simulator that does not have channels for the exit of steam, thereby reducing the efficiency of the steam generator.

A device with a flame simulation effect is also known, which is intended to improve the simulation of real fire, which, in particular, should enhance the effect of simulating a flame and / or smoke and includes: a substrate with holes; a light source that creates a flame effect; a container containing liquid, and in this container there is a space above the liquid level, including a vapor exit channel; an ultrasonic transducer whose transforming surface is in contact with the liquid and which forms steam in the indicated space above the liquid level; means for generating an air flow along a path entering the space above the liquid level and passing through the steam outlet channel, wherein the exit channel is positioned so that air leaves the container under the substrate with openings; and means of forming an upward flow of air from the substrate with holes (RU 2434181, 2010).

However, since in the known device in the process of ultrasonic crushing of water, “cold” steam is formed, the installation of additional means is required to control its flows, which complicates the overall design of the device and its maintenance. Also, the known device has limited possibilities in controlling the modes of vaporization and its intensity, because It is supposed to use only one ultrasonic transducer, which limits the resource of its operation, since the steam production load is distributed exclusively to one evaporator. This requires regular preventive and repair work to clean and replace the evaporator.

The closest analogue of the present utility model is a flame and smoke simulator including a fuel simulator with openings, a light source, an aerosol generator including at least one fluid supply system connected to a fluid supply duct system, and at least ultrasonic transducers , each said ultrasonic transducer is connected to a corresponding channel for supplying liquid with the possibility of aerosol formation at the outlet of said channel, and at least each channel for The fluid is combined with a corresponding hole made in the fuel simulator, with the possibility of forming a channel for aerosol exit through the fuel simulator (RU 137598, 2014). A known device may include a valve and a liquid level sensor, a system for creating an upward flow of air in the form of a fan, means for heating the upward flow of air.

At the same time, the aerosol formed in the known design will be abundant and unnatural. Since the device does not provide a damping chamber for the aerosol flow rate, so excessive vaporization will cause the consumer to observe a dense curtain of smoke during operation of the device, rather than a light smoke rising during combustion, i.e. the quality of the simulation of smoke does not match that which is formed during the natural combustion of solid high-quality fuel. In addition, the continuous operation of the device for a long time is associated with the release of so much steam into the room that can lead to an uncontrolled change in humidity in the room, which, in turn, can lead to negative consequences for others. At the same time, the known device does not provide humidity control elements.

The technical problem of the claimed utility model is the low efficiency of the device and unregulated vaporization.

The technical result is an improvement in the quality of steam simulation while increasing the efficiency of the device, including by expanding the functionality by giving an additional function of humidification of the air in the room during the controlled steam simulation of smoke.

The claimed technical result is achieved by the fact that the claimed device for simulating flame and smoke, comprising a fuel simulator located in a housing on a substrate, the substrate is configured to allow air and steam to simulate smoke, light sources located below and configured to illuminate the fuel and steam simulator , an aerosol generator for generating steam, including ultrasonic evaporators, the converting surfaces of which are in contact with the liquid and forming steam above the liquid level, flooded inserted into the fluid supply system, a fan for forced direction of air and steam flow, characterized in that the fluid supply system comprises a container and a micro-container hydraulically connected to each other, filled with liquid, and an air mass distribution and filling chamber made of translucent material for passing radiation from light sources, the fan is installed on the microcontainer, and ultrasonic evaporators are located on the bottom of the microcontainer , the container is equipped with an air duct that has an exit to the chamber for distributing and filling the air mass, the substrate is provided with a groove for passing air and steam simulating smoke from the above chamber, and ventilation windows for discharging air and steam are made in the housing.

A hygrostat and a hygrometer connected to ultrasonic evaporators can additionally be placed in the housing. A hygrostat and a hygrometer provide an additional function of regulating the desired humidity in the room. Hygrostat provides the ability to maintain a given humidity by the user in the room. The hygrometer enables the user to set the required humidity level by real-time monitoring of humidity.

As ultrasonic evaporators can be used any device known for these purposes, in particular of the Fogger type, also with diameters of ceramic membranes from 4 to 30 mm.

A control panel is placed on the housing, electrically connected to a control unit connected to the power supply.

The liquid filled container may be provided with an antibacterial insert or the inner surface is provided with an antibacterial coating containing silver or another antibacterial substance. In the container, an additional liquid level sensor can be placed in the container and connected to ultrasonic evaporators located in the microcontainer. If the water level drops below the reference mark, the liquid level sensor is activated to turn off the ultrasonic evaporators, stopping the smoke simulation.

The inventive device is configured to be connected to a power supply, equipped with an electrical part supplying ultrasonic evaporators, a fan, sensors, light sources and other electrical elements of the device.

An air duct installed on the microcontainer, partially filled with liquid, ensures the transportation of air mass (air and steam) from the microcontainer with ultrasonic evaporators placed in it to the distribution and filling chamber. The air mass distribution and filling chamber slows down the speed of the air flow, accumulates steam and passes it through a groove located in the substrate, visually simulating the effect of natural smoke generation, without jerks and jerks, because the chamber of distribution and filling of the air mass is a physical absorber of the speed of the air flow (steam), accumulation and gradual release of steam due to physical forces. The air mass distribution and filling chamber has a sectional area larger than the air duct, i.e. when it enters the chamber from the duct, the air flow rate decreases, and the pressure on the chamber walls increases, which ensures the steam exit through the groove, but with an extinguished flow rate. If the flow rate has fallen, then the air mass is distributed throughout the interior of the chamber, accumulating in it.

The movement of air mass from the room through the microcontainer to the distribution and filling chamber is ensured by the draft created by the fan installed on the microcontainer.

A microcontainer with ultrasonic evaporators placed in it, immersed in a liquid, can be heated, heated, for example, by heating elements or PTC elements.

The distribution and filling chamber is made of translucent material, for example, any known transparent plastic.

Light sources located under the distribution and filling chamber illuminate a solid fuel simulator, such as firewood, as well as water vapor simulating smoke. The light sources are configured to change the intensity of the glow and the color of the light radiation. In addition, light sources by means of heating create a convective flow of air mass, creating an upward flow passing through a groove in the substrate.

The device may further comprise an air filter located at the inlet of the air flow and purifying the air mass from dust, other suspended particles and harmful impurities in the air. The draft created by the fan allows for the flow of air, which, passing through the duct and enriched with water dust, goes back into the room cleaned. As an air filter, any filter known for these purposes, for example, a carbon filter, can be used.

The device may further comprise a liquid softener or filter, preventing the formation of scale on the walls of the container and the microcontainer, which prevents the duct from overgrowing with hardness salts.

The device may include an aromatic capsule or container for aromatic oils, which is located in the microcontainer or at the inlet of the air stream. The air stream passing through the duct through the aromatic capsule is enriched with aromatic substances, which subsequently return to the room, aromatizing it.

Comparison of the claimed device with the prototype allows us to conclude that the claimed device meets the criterion of novelty, because It differs in the following features:

- contains, as a fluid supply system, a container and a micro-container hydraulically communicated with each other, filled with liquid:

- additionally contains a chamber for distribution and filling of the air mass made of translucent material for transmission of radiation from light sources;

- placement of the chamber of distribution and filling of the air mass under the substrate;

- placing the fan in the microcontainer to create traction in the duct installed at the entrance to the container;

- the location of the duct in such a way that it provides transportation of the air mass through the microcontainer to the chamber distribution and filling of the air mass;

- placement of ultrasonic evaporators on the bottom of the microcontainer;

- performing in the substrate a groove for passing the air mass from the distribution chamber and filling the air mass;

- the presence in the housing of ventilation windows for the release of air mass. The specified set of essential features ensures the receipt of the claimed technical result, because The claimed design makes it possible to simultaneously use the device as a humidifier, while the presence of an air mass distribution and filling chamber under the substrate makes it possible to provide controlled vapor simulation of smoke close to natural. In addition, the presence of one duct instead of a plurality of channels, each of which is connected to an ultrasonic transducer, simplifies the design and eliminates the risk of fouling, subsidence of steam on the walls, reduction of the cross-section, unstable operation of the device, and eliminates abundant and uncontrolled steam output.

In addition, the claimed design provides the expansion of the functional characteristics of devices for simulating flame and smoke by providing the possibility of placement in the container, microcontainer, duct, distribution chamber and filling the air mass of additional elements (filters, sensors, aromatic capsules, hygrometer and hygrostat), which allows expand the arsenal and range of combined devices that combine several functions that are useful to the consumer at the same time.

The inventive device is illustrated by the following figures.

In FIG. 1 schematically shows the location of the main structural elements from the rear wall of the housing.

In FIG. 2 also shows a realistic image.

In FIG. 3 schematically shows the location of the main structural elements from the front wall of the housing

In FIG. 4 shows a section AA of FIG. 3

In FIG. 5 is a schematic side view of the device.

In FIG. 6 shows a photograph of the device with the side wall of the housing removed.

The inventive device consists of a housing, inside of which on the substrate 1 there are elements imitating solid fuel, for example, firewood. Light sources 3 are placed on the base of the housing under the underside 1. A groove 2 is made in the underlay 1 to allow air and steam to escape from the distribution and filling chamber 7 of the air mass. Inside the housing there is a container 4 filled with a liquid, for example, water. An antibacterial insert 5 is placed inside the container 4 and is placed so that an incoming air stream can pass through it. At the inlet, the container 4 is equipped with an air duct 6, which allows the air mass to pass through the container 4 and the microcontainer 14, in communication with the chamber 7 of the distribution and filling of the air mass. The chamber 7 of the distribution and filling of the air mass is made of transparent plastic and is located under the substrate 1. The microcontainer 14 is hydraulically connected to the container 4, is equipped with a fan 8, which transports the directed air flow through the container 4 to the duct 6 through the microcontainer 14 to the filling and distribution chamber of the air mass 7. The microcontainer 14 is filled with liquid coming from the container 4, ultrasonic evaporators 9 are mounted in the liquid, mounted on the bottom of the microcontainer 14 and electrically connected Inonii a humidistat and hygrometer 10 to maintain a predetermined humidity. The cross-sectional area of the chamber 7 of the distribution and filling of the air mass has a cross-sectional area greater than the duct 6.

At the inlet of the duct 6 in the container 4, an air filter 11 is installed, which cleans the incoming air mass from dust of other suspended particles. A filter 12 is placed in the container 4, preventing the formation of salt deposits on the walls of the container 4. The device is equipped with an aromatic capsule 13, flavoring the steam coming from ultrasonic emitters 9. The microcontainer 14 is heated for additional processing of liquid from bacteria in case of prolonged non-use of the device. In the container 4 is placed a liquid level sensor 15. The device comprises a control unit connected to an electrical part, providing connection of light sources 3, fan 8, ultrasonic evaporators 9, hygrostat and hygrometer 10, liquid level sensor 15 with an external power source, a control panel on the outside of the case (not shown). The housing has a ventilation window for the natural circulation of air flow.

A device with the effect of simulating flame and smoke works as follows. The consumer turns on the device, providing connection to an external power source. Liquid is poured into the container 4 by pouring it into the neck of the container, which can be located under decorative firewood or behind the control panel, providing control of the liquid level by means of the liquid level sensor 15, the readings of which are transmitted to the control panel. The consumer on the control panel sets the required humidity level in the room, the signal is fed to a hygrostat and a hygrometer 10 connected to ultrasonic evaporators 9. When the device is turned on, the electric power supplies the light sources 3, the light flux from which illuminates the firewood placed on the substrate 1 and upward water steam generated as a result of the operation of ultrasonic evaporators 9, placed in the microcontainer 14 with the liquid coming from the container 4 to which the microcontroller 14 is connected hydraulically Eski, such as communicating vessels. Ultrasonic evaporators 9 are immersed in a liquid that is heated to a temperature of about 60 ° C, which ensures the death of the Legionella bacterium, which usually lives in a natural environment, in places where water is present. The implementation of the microcontainer 14 small in volume allows for efficient heating of the water, saving energy. As a result of the operation of ultrasonic evaporators 9 above the liquid level in the microcontainer 14, an air-drop mixture is formed. When the fan 8 is turned on, draft is created and air through the window in the housing enters from the room into the air duct 6, passes through the air filter 11, the aromatic capsule 13 of the microcontainer 14 into the air mass distribution and filling chamber 7, where the air flow rate is suppressed and due to physical forces steam evenly flows out through groove 2, simulating a stream of smoke. Passing through the flame and vapor simulation chamber, the air stream enriched with steam and flavor enters the room. In the process, the hygrometer 10 determines the existing humidity in the room, compares the value with the data entered by the user. If the humidity in the room is less than the one set by the user, then the hygrometer 10 instructs the hygrostat to turn on the ultrasonic evaporators 9. Upon reaching the user-specified humidity in the room, the hygrometer instructs the hygrostat to turn off the ultrasonic evaporators and continues to monitor the humidity. Further, with a decrease in humidity, the algorithm cycle repeats. The liquid level sensor 15 turns off the ultrasonic evaporators 9, when it reaches the low water level. In this case, the device continues to work, but without steam simulation of smoke, saving energy.

The inventive device can improve the efficiency of the simulation of flame and smoke, provides enhanced functionality due to the ability to maintain a given humidity in the room with a high resource of evaporators, because to achieve a given humidity, the evaporators work less time, eliminates fouling of the duct, which ensures stable operation of the device. In addition, preventive and repair work on cleaning and replacing evaporators should be carried out less frequently, including due to the absence of salts and other compounds in the water, pollution of decorative parts and surfaces of the premises is excluded, which increases the overhaul period. In addition, the claimed device allows for additional disinfection of water by heating the liquid in the microcontainer, purification of the incoming air and its aromatization.

Claims (8)

1. A device for simulating flame and smoke, comprising a fuel simulator located on a substrate, a substrate configured to allow air and steam to simulate smoke, light sources located below and configured to illuminate a fuel and steam simulator, an aerosol generator for generating steam including ultrasonic evaporators, the converting surfaces of which are in contact with the liquid and forming steam above the level of the liquid poured into the liquid supply system, a fan for forced air and steam flow directions, characterized in that the fluid supply system comprises a container and a microcontainer hydraulically connected to each other, filled with liquid, an air mass distribution and filling chamber made of translucent material for transmitting radiation from light sources is placed under the substrate, the fan is installed on the microcontainer, and ultrasonic evaporators are placed on the bottom of the microcontainer, the container is equipped with an air duct that has an outlet to the chamber distribution and filling of the air mass, the substrate is provided with a groove for the passage of air and steam simulating smoke from the above chamber, in the housing there are ventilation windows for the release of air and steam. 2. The device according to p. 1, characterized in that the cross-sectional area of the chamber of distribution and filling of the air mass has a cross-sectional area greater than the cross-sectional area of the duct. 3. The device according to p. 1, characterized in that the microcontainer is made with heating. 4. The device according to p. 1, characterized in that the container contains an aromatic capsule made with the possibility of the flow of air through it. 5. The device according to claim 1, characterized in that an air filter is placed at the inlet of the air flow. 6. The device according to claim 1, characterized in that a liquid level sensor is installed in the container. 7. The device according to claim 1, characterized in that a filter is placed in the container, preventing the formation of salt deposits on the walls of the container. 8. The device according to claim 1, characterized in that transparent plastic is used as the translucent material of the chamber for distribution and filling of the air mass.

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