RU175788U1 - Artificial fireplace - Google Patents

Abstract

The utility model relates to devices for electric fireplaces and decorative lamps. An artificial fireplace, characterized in that for visualization of the combustion process an optical combination of an imaginary video image of flame languages is used, formed on a video image forming tool made in the form of a liquid crystal display, with a fuel cell model located in the internal volume of the combustion chamber with a frontal opening, through a beam splitter plate, located at an angle to the video imaging tool and the fuel cell layout, as well as using dynamic LED lighting to simulate the lighting of the combustion chamber during the demonstration of the burning scene. In an artificial fireplace, the video imaging tool is made in the form of a liquid crystal display and, in addition, a synchronization system for video-audio stream and controlled modular dynamic backlight of the combustion chamber and the fuel cell layout is used using the control unit and a photodetector that reads information from the video image of the sync line about the required level glow of each backlight module. In addition, the back wall of the combustion chamber can be made in the form of an additional liquid crystal display, part of the fuel chamber backlight modules can be made in the form of a video projector, the photodetector can be made in the form of a single-board computer (a computer assembled on one printed circuit board on which a microprocessor is installed , RAM, input-output systems and other modules necessary for the functioning of the computer); the layout of the fuel cell can be placed at a distance from the bottom wall of the combustion chamber using decorative tripods, and the video image of the tongues of flame can be represented as a single fragment that displays the complete combustion cycle of the layout of the fuel cell. The technical result is the most realistic reproduction of the burning scene of a fuel cell.

Description

The utility model relates to devices for electric fireplaces and decorative lamps. In particular, to devices for visualizing the combustion process of a fuel cell prototype with maximum realism for decorative purposes.

A device for simulating flame and smoke is described in the certificate of the Russian Federation for utility model No. 150453, IPC F24C 7/00, publ. 02/20/2015, including a housing with a substrate, under which there is a container for liquid, a steam distribution device, a heating element with two through holes and a light source. In this case, the substrate is made in the form of a fuel simulator with the possibility of extension from the housing; the liquid container contains a lid, and the steam distribution device contains openings for steam inlet and outlet, wherein the steam inlet hole is in contact with one of the openings in the heating element, and the lid of the liquid container is in contact with the other opening in the heating element. In this case, the liquid container and the steam distribution device are located above the heating element. But this device is difficult to maintain.

The closest analogue is an artificial fireplace, described in the patent of the Russian Federation for invention No. 2588092, IPC F24C 7/00, publ. 03/20/2016. An artificial fireplace contains a portal with an open or transparent window that allows you to direct the line of sight of the observer into the portal. The portal consists of elements of the hearth located on the first and second sections, essentially perpendicular to each other, means forming an image and designed to demonstrate the image of the flame, the image of the back of the fireplace and / or the element of the hearth and dichroic mirror. The dichroic mirror serves to combine the element of the hearth and / or image of the back of the fireplace with the image of the flame to create the impression of a live fire. However, for such a solution, the imaginary video image of the model of the furnace element and the back of the furnace is unsatisfactory in several parameters with the video image of the flame languages, which makes it impossible to create realistic dynamic illumination of the furnace chamber, since with this solution the burning scene is physically divided into two independent parts by the plane of the dichroic mirror. The ratio of the opening area to the frontal projection area is also unsatisfactory. In the ideal case, this ratio is 1 - the frontal projection area is equal to the opening area. Also, with this arrangement, it is practically impossible to use additional features of the combustion scene visualization: projecting a video image onto the fuel cell layout and the back wall of the combustion chamber using an LED video projector or using a second liquid crystal display on the rear wall of the combustion chamber. Also, as a result of the formation of an imaginary image of the layout of the fuel cell of the rear of the combustion chamber using a mirror beam splitter plate having a real thickness, the effect of doubling the imaginary image observed inevitably over the entire area of the scene is inevitably manifested.

The objective of this utility model is to create an artificial fireplace with enhanced consumer qualities.

The technical result is the most realistic reproduction of the burning scene of the layout of the fuel cell while increasing manufacturability, reliability of the product and reducing size. This is achieved by the fact that in an artificial fireplace, characterized in that for visualization of the combustion process, an optical combination of an imaginary video image of flame languages is used, formed on a video image forming tool made in the form of a liquid crystal display, with a fuel cell layout located in the internal volume of the combustion chamber with the front an aperture, through a beam splitter plate, located at an angle to both the video imaging tool and the fuel cell layout nt, in contrast to the known one, in an artificial fireplace the video imaging tool is placed outside the observer’s field of vision, and a synchronization system for video-audio stream and controlled modular LED dynamic lighting of the combustion chamber and fuel cell layout using the control unit and a photodetector that reads information about the necessary level of luminescence for each module of LED dynamic backlighting from the sync line video image displayed on the video generation tool The images. In addition, the back wall of the combustion chamber can be made in the form of an additional liquid crystal display, part of the LED dynamic backlight modules of the fuel chamber can be made in the form of a mini LED video projector, the photodetector can be replaced by a single-board computer that receives information from the sync line directly from the video image file. The layout of the fuel cell can be placed at a distance from the bottom wall of the combustion chamber using decorative tripods, and the video image of the flame tongues can be represented as a single fragment that displays the complete combustion cycle of the layout of the fuel cell.

The utility model is illustrated by figures 1 and 2.

In FIG. 1 shows a diagram of a frame of a video image on a liquid crystal display during the operation of an artificial fireplace, as well as a general view of the artificial fireplace.

In FIG. 2 is a schematic cross-sectional view of an artificial fireplace with an internal combustion chamber arrangement.

In FIG. 1 shows a layout diagram of a video image on a liquid crystal display 1, consisting of a video zone of a flame 2 and a video zone of a sync line 3, as well as a general view of an artificial fireplace, consisting of a liquid crystal display 1, located on the top wall 4 of a combustion chamber 5. The video image of a sync line 3 is part video image formed on the liquid crystal display 1, in which information about the luminosity level of each LED dynamic backlight module is encoded internal chamber 5 at a given time. The combustion chamber 5 is made with a frontal opening, and a fuel cell 6 is located in the internal volume of the combustion chamber 5. A beam splitter plate 7 is located inside the combustion chamber 5 at an angle to the video imaging tool in the form of a liquid crystal display 1 and to the layout of the fuel cell 6. fuel cell 6 plays a major role in the visualization. It is made of translucent material and with maximum accuracy copies the real fuel cell, which was used in the process of preparing and filming video images of flames. The layout of the fuel cell 6 is placed in the combustion chamber 5 either directly on the bottom wall 8, or fixed at a certain height from the bottom wall 8 using two decorative tripods 9, which allows you to visualize the combustion process of the layout of the fuel cell 6, completely covered by the flames. The combination of the imaginary video image of the tongues of flame 10 formed on the liquid crystal display 1 in the zone of the image of the languages of flame 2 with the layout of the fuel element 6 occurs using a beam splitter plate 7, located at an angle to the liquid crystal display 1 and to the layout of the fuel element 6. The front opening of the combustion chamber 5, accessible to the user's observation, framed by a decorative frame 11. At the bottom of the front opening of the combustion chamber 5 there is a decorative grill 12, as well as a control panel 13 suit solid fireplace. On the top wall 4 of the combustion chamber 5, in addition to the image forming means in the form of a liquid crystal display 1, there is a control unit 14, a power supply 15, a means for reproducing video-audio recordings, for example, a media player 16 and a pair of stereo speakers 17.

In FIG. 2 shows a cross-section and the internal structure of the combustion chamber 5. To achieve maximum realism of the burning scene in an artificial fireplace, a device for controlled LED dynamic lighting of the combustion chamber 5 and the layout of the fuel cell 6 simulating lighting during combustion is used. Simulation is carried out using a variety of controlled LED dynamic modules, conditionally grouped and hidden from the observer, located in certain areas of the combustion chamber 5 and the layout of the fuel element 6. Groups of LED dynamic lighting modules of the upper part of the combustion chamber 18 and 19 are located inside the combustion chamber 5, on the upper wall 4, above the layout of the fuel element 6. A group of LED dynamic lighting modules 20, simulating the glow of coal, is located inside the combustion chamber 5 for decoration Willow bracket 9 inside the layout of the fuel cell 6, made of translucent material. A group of LED dynamic backlight modules 21 is located inside the combustion chamber 5 on the decorative bracket 9 behind the layout of the fuel element 6 in front of the rear wall 22 of the combustion chamber 5. In the lower part of the combustion chamber 5 between the beam splitter plate 7 and the lower wall of the combustion chamber 8 behind the control panel for an artificial fireplace 13 there is a group of LED dynamic backlight modules 23. In addition, on the inner surface of the upper wall 4 of the combustion chamber 5 in front of the beam splitter plate 7 directly opposite On the video image of sync line 3 displayed on the liquid crystal display 1, there is a photodetector 24, which is a series of photosensitive elements that receive information about the luminance level of elements of the video image of sync line 3. The number of photosensitive elements in the photodetector 24 corresponds to the number of video elements of the sync line 3. Luminous intensity of LED modules dynamic lighting of various zones of the combustion chamber 5 depends on the nature of the image flame at a given time and other video effects played on the liquid crystal display 1, and encoded in the video image of the sync line 3. The groups of LED dynamic backlight modules 18, 19, 20, 21, 23 are controlled using the control unit 14, the control signal to which is supplied from a photodetector 24, which is either a series of photosensitive elements mounted directly opposite the video area of the sync line 3 on the liquid crystal display 1, or in the form of of a paid computer — a computer assembled on one printed circuit board on which a microprocessor, RAM, I / O systems and other modules are installed, which are necessary for the operation of a computer that programmatically analyzes the sync line 3 video image and generates control commands for LED dynamic backlight modules, conditionally combined into groups 18, 19, 20, 21, 23. In the process of reproducing a video image, each photosensitive element of the photodetector 24 corresponds to one of the elements These are synchroster video images 3. In addition to groups of LED dynamic backlight 18, 19, 20, 21, 23 of the combustion chamber 5 located inside the device, it is possible to connect additional external groups of LED dynamic backlight. Depending on their location, the control unit 14 generates individual control commands. In the case of installing a fireplace in a separate decorative portal, additional external groups of LED dynamic lighting, significantly increase the decorative quality of the product. At the moment, to implement a system of LED dynamic lighting, the most appropriate solution is to use LED strips / modules with digital addressing of elements. Such tapes are an array of LEDs with controllers, which allows using a digital signal to inform the individual intensity and color of the glow to each element of the array. This allows us to simplify the circuitry of the device and increase maintainability thanks to the modular layout of the backlight groups. However, in some cases, it is necessary to use separate LEDs controlled by a pulse-width modulated signal generated directly by the control unit 14.

An artificial fireplace works as follows. Using the control panel 13, located at the bottom of the product, made in the form of a combustion chamber 5 with a decorative frame 11, the type / intensity of combustion, the volume of sound effects are selected and a command is given to start playback. In the process of operation of the device on the liquid crystal display 1 in the zone of the video image of the flame 2, video fragments of the selected type of intensity of the flame 2 are played for a duration of 10 minutes, and in the frame zone of the sync line 3 the corresponding video image is played. Each video fragment contains a video image of the flames 2 formed during the complete cycle of combustion of the layout of the fuel element 6, and the corresponding sync line 3 from ignition and ignition to complete burnout of the fuel.

The visual effect of the combustion of the layout of the fuel cell 6 is achieved by optical alignment of the imaginary video image of 10 flame languages and other video effects with the layout of the fuel element 6 located in the combustion chamber 5. An imaginary video image of 10 flame languages is formed using the video image of the flame 2 displayed on the liquid crystal display 1 , and its reflection from the beam splitter plate 7. During the playback of video fragments, the photodetector 24 receives data on the luminosity of the elements in de-images of the sync line 3, on the basis of which the control unit 14 generates control commands for the dynamic LED modules of the combustion chamber and the fuel cell layout combined into groups 16, 17, 18, 19, 22. As a result of the exact combination of the imaginary video image of 10 flame languages with the fuel cell layout 6, the exact synchronization of the LED dynamic backlight modules and sound effects using sync line 3 builds the overall picture of the burning scene.

Thus, as a result of work on the design of an artificial fireplace, it was possible to improve manufacturability, consumer and decorative qualities of the product due to a significant reduction in the dimensions of the device in height while maintaining a satisfactory size of the front opening, which allows you to embed an artificial fireplace in a standard module of cabinet furniture; and also to achieve maximum realistic visualization of the fuel cell burning scene at this stage in the development of technology. In addition, the effect of doubling the imaginary image is minimized, since it will be observed only on the imaginary video image of the flame languages, and not over the entire area of the frontal opening in the imaginary image of the rear of the combustion chamber, in contrast to the closest analogue.

Claims (6)

1. An artificial fireplace, characterized in that for visualization of the combustion process an optical combination of an imaginary video image of flame languages is used, formed on a video image forming tool made in the form of a liquid crystal display, with a fuel cell model located in the internal volume of the combustion chamber with the front opening, through a beam splitter a plate located at an angle to both the video imaging tool and the fuel cell layout, characterized in that in an artificial fireplace, the video imaging tool is placed outside the observer's field of view, and a synchronization system for video-audio stream and controlled modular LED dynamic backlight of the combustion chamber and fuel cell layout is applied using the control unit and a photodetector that reads information about the required level of illumination of each LED module dynamic backlight from the video image of the sync line displayed on the video imaging tool. 2. An artificial fireplace according to claim 1, characterized in that the rear wall of the combustion chamber is made in the form of an additional liquid crystal display. 3. An artificial fireplace according to claim 1, or 2, characterized in that part of the backlight modules of the fuel chamber are made in the form of a video projector. 4. An artificial fireplace according to claim 1 or 2, or 3, characterized in that the photodetector and control unit are replaced with a single board computer. 5. An artificial fireplace according to claim 1 or 2, 3, or 4, characterized in that the layout of the fuel element is placed at a distance from the bottom wall of the combustion chamber using decorative tripods. 6. An artificial fireplace according to Claim. 1 or Clause 2, or Clause 3, or Clause 4, or Clause 5, characterized in that the video image of the tongues of flame is presented as a single fragment displaying the complete combustion cycle of the fuel cell model.

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