CN111790090A - Interactive control method and system for simulating flames - Google Patents

Abstract

The invention discloses an interactive control method and system for simulating flames, wherein the system comprises flame simulation equipment and fire extinguishing equipment; the flame simulation equipment comprises a first induction module, a first control module, a second control module and a simulated flame generation module; the fire extinguishing equipment is provided with a signal transmitting module; the method comprises the following steps: the signal transmitting module sends out a first induction signal, and the first induction module is used for receiving the first induction signal; the first control module judges whether the first induction signal received by the first induction module accords with the corresponding induction signal type under the current simulated flame type according to the corresponding relation between the simulated flame type and the induction signal type, and if so, the second control module adjusts the simulated flame generated under the current simulated flame type. According to the scheme, the fire extinguishing scene is truly simulated through signal interaction between the fire extinguisher and the flame simulation equipment, and the requirement of fire safety training is effectively met.

Description

Interactive control method and system for simulating flames

Technical Field

The invention relates to the field of flame generation devices, in particular to an interactive control method and system for simulating flames.

Background

With the development of scientific technology, many simulated flame generating devices appear on the market. However, most of the simulated flames in the current market are formed by simulating light sources of common bulbs through methods such as projection, reflection, diffraction, refraction and the like, the colors of the flames are monotonous and stiff, various changes which are needed when real flames are burnt are lacked, and the visual effect of the clearly simulated flames is not high. And the existing simulated flame generating device can not effectively interact with the fire extinguisher, can not simulate the real fire-fighting scene, and can not meet the requirement of fire safety training.

Disclosure of Invention

Therefore, a technical scheme for interactive control of simulated flames needs to be provided for solving the problem that the existing simulated flame generation device cannot effectively interact with a fire extinguisher and cannot meet the requirement of fire safety training.

In order to achieve the above object, the present invention provides an interactive control system for simulating flames, the system comprising a flame simulating device and a fire extinguishing device; the flame simulation equipment comprises a first induction module, a first control module, a second control module and a simulated flame generation module; the first induction module and the second control module are respectively connected with the first control module, and the second control module is used for controlling the simulated flame generation module to generate simulated flames; the fire extinguishing equipment is provided with a signal transmitting module;

the signal transmitting module is used for transmitting a first induction signal, and the first induction module is used for receiving the first induction signal;

the first control module is used for judging whether the first induction signal received by the first induction module accords with the corresponding induction signal type under the current simulated flame type according to the corresponding relation between the simulated flame type and the induction signal type, and if so, the simulated flame generated under the current simulated flame type is adjusted through the second control module.

As an alternative embodiment, "adjusting, by the second control module, the simulated flames produced under the current simulated flame type" includes:

and when the first induction module continuously receives a first induction signal which accords with the corresponding induction signal type under the current simulated flame type in unit time, the size of the simulated flame is reduced according to the echelon.

As an alternative embodiment, the method comprises:

when the first sensing signal received by the first sensing module is judged not to be in accordance with the corresponding sensing signal type under the current simulated flame type, the size and the color of the simulated flame generated under the current simulated flame type are kept unchanged.

As an alternative embodiment, the signal emitting module is a laser reflector, and the laser reflector is arranged at the position of a nozzle of the fire extinguisher.

As an optional embodiment, the first sensing module includes a plurality of groups of laser sensors, the laser frequency bands sensed by different laser sensors are different, and the plurality of groups of laser sensors are arranged on the outer shell of the flame simulation device.

As an optional embodiment, the flame simulation device comprises a housing, the housing comprises a storage cavity, the simulation generation module is arranged in the storage cavity, and the flame simulation generation module comprises a liquid storage container, an atomization device, a blowing device and a light source device; (ii) a

The liquid storage container comprises a liquid storage cavity, the atomization device is arranged in the liquid storage cavity, and the atomization device is used for atomizing liquid in the liquid storage cavity;

the side wall of the liquid storage container is provided with an air guide opening, the air blowing device is connected with the air guide opening through an air guide pipe, and the air blowing device is used for blowing air and pressurizing the liquid storage cavity;

a first mist outlet channel is formed in the shell, and a second mist outlet channel aligned with the first mist outlet channel is formed in the liquid storage container;

the light source device is arranged below the first fog outlet channel and can emit light sources irradiating towards the first fog outlet channel.

As an optional embodiment, the device further comprises a mist guide groove, wherein the mist guide groove is a through groove which is vertically opened along the longitudinal direction; the fog guide groove is detachably sleeved on the first fog outlet channel.

As an alternative embodiment, the second control module comprises a blowing device control module, a light source device control module and an atomizing device control module; the first control module is respectively and electrically connected with the air blowing device control module, the light source device control module and the atomization device control module;

the air blowing device control module is electrically connected with the air blowing device, the light source device control module is electrically connected with the light source device, and the atomization device control module is electrically connected with the atomization device.

As an optional embodiment, a speaker is further disposed in the storage chamber, and the second control module further includes an audio control module;

the first control module is electrically connected with the audio control module, and the audio control module is electrically connected with the loudspeaker.

The invention also provides an interactive control method for simulating flames, which is applied to the interactive control system for simulating flames, which comprises flame simulation equipment and fire extinguishing equipment; the flame simulation equipment comprises a first induction module, a first control module, a second control module and a simulated flame generation module; the first induction module and the second control module are respectively connected with the first control module, and the second control module is used for controlling the simulated flame generation module to generate simulated flames; the fire extinguishing equipment is provided with a signal transmitting module;

the method comprises the following steps:

the signal transmitting module sends out a first induction signal, and the first induction module is used for receiving the first induction signal;

the first control module judges whether the first induction signal received by the first induction module accords with the corresponding induction signal type under the current simulated flame type according to the corresponding relation between the simulated flame type and the induction signal type, and if so, the second control module adjusts the simulated flame generated under the current simulated flame type.

Different from the prior art, the technical scheme provides an interactive control method and system for simulating flames, wherein the system comprises flame simulation equipment and fire extinguishing equipment; the flame simulation equipment comprises a first induction module, a first control module, a second control module and a simulated flame generation module; the first induction module and the second control module are respectively connected with the first control module, and the second control module is used for controlling the simulated flame generation module to generate simulated flames; and the fire extinguishing equipment is provided with a signal transmitting module. The method comprises the following steps: the signal transmitting module sends out a first induction signal, and the first induction module is used for receiving the first induction signal; the first control module judges whether the first induction signal received by the first induction module accords with the corresponding induction signal type under the current simulated flame type according to the corresponding relation between the simulated flame type and the induction signal type, and if so, the second control module adjusts the simulated flame generated under the current simulated flame type. According to the scheme, the fire extinguishing scene is truly simulated through signal interaction between the fire extinguisher and the flame simulation equipment, and the requirement of fire safety training is effectively met.

Drawings

FIG. 1 is a schematic structural diagram of a flame simulating apparatus according to an embodiment.

Fig. 2 is a schematic structural view of an object placing cavity of the flame simulation apparatus according to the specific embodiment.

FIG. 3 is a schematic structural diagram of a liquid storage container of the flame simulating apparatus according to the embodiment.

Fig. 4 is a schematic structural view of a mist guiding groove of the flame simulation equipment according to the specific embodiment.

Fig. 5 is a schematic view of a disassembly and assembly structure of the mist guide groove of fig. 4.

FIG. 6 is an exploded view of a flame simulating apparatus according to an embodiment.

FIG. 7 shows the connection relationship of the circuit control module of the flame simulating apparatus according to the embodiment.

FIG. 8 is a schematic structural diagram of a flame simulating apparatus according to another embodiment.

Fig. 9 is a schematic diagram of a driving circuit of a blowing device of the flame simulation apparatus according to the embodiment.

FIG. 10 is a schematic diagram of a driving circuit of a light source device of the flame simulating apparatus according to the embodiment.

FIG. 11 is a schematic diagram of a driving circuit of an atomizing device of the flame simulating apparatus according to the embodiment.

FIG. 12 is a schematic diagram of a driving circuit of a speaker of the flame simulating apparatus according to an embodiment of the invention.

FIG. 13 is a schematic diagram of a detection water inlet and outlet control circuit of a liquid level meter of the flame simulating apparatus according to the embodiment.

FIG. 14 is a schematic view of a water inlet driving circuit of the flame simulating apparatus according to the embodiment.

FIG. 15 is a schematic diagram of a drain driving circuit of the flame simulating apparatus according to an embodiment of the present invention.

FIG. 16 is a schematic diagram of a signal receiving circuit of a wireless communication module of the flame simulating apparatus according to an embodiment of the invention.

FIG. 17 is a schematic structural diagram of an interactive control system for simulating flames according to an embodiment.

FIG. 18 is a flow chart of a method for interactive control of simulated flames according to an embodiment.

Description of reference numerals:

1. a housing; 11. a top cover; 111. a first mist outlet channel; 12. a base; 121. a cover plate; 1211. a handle fixing frame;

2. a storage cavity; 21. a reservoir; 211. a liquid storage cavity; 2111. a wind guide opening; 2112. an air guide pipe; 2113. A compartment; 2114. a partition plate; 2115. a card slot; 2116. a connecting line outlet; 212. a cover body; 2121. a second mist outlet channel; 213. a box body; 214. a first fixed support; 215. a second fixed support; 216. a step-up assembly; 22. an atomizing device; 23. a blower device; 24. a light source device; 241. an LED lamp;

3. a mist guide groove;

4. fixing a bracket;

5. a liquid level meter; 51. a first liquid level meter; 52. a second level gauge;

6. a circuit control system; 61. a first control module; 62. a second control module; 621. a blower device control module; 622. a light source device control module; 623. an atomization device control module; 624. an audio control module; 625. a liquid level meter control module; 626. a water inlet motor control module; 627. the water outlet motor control module; 628. an LED display control module; 63. a wireless communication module;

7. a speaker; 8. a water inlet motor; 9. a water outlet motor; 10. a power supply module; 101. a laser signal detection module; 102. an LED display; 11. flame simulation equipment; 111. a first sensing module; 112. A first control module; 113. a second control module; 114. a simulated flame generation module; 12. a fire extinguishing apparatus; 121. and a signal transmitting module.

Detailed Description

To explain technical contents, structural features, and objects and effects of the technical solutions in detail, the following detailed description is given with reference to the accompanying drawings in conjunction with the embodiments. Examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout.

As shown in FIG. 17, a first aspect of the present invention provides an interactive control system for simulating flames, the system comprising a flame simulating apparatus 11 and a fire extinguishing apparatus 12; the flame simulating device 11 comprises a first sensing module 111, a first control module 112, a second control module 113 and a simulated flame generating module 114; the first sensing module 111 and the second control module 113 are respectively connected with the first control module 112, and the second control module 113 is used for controlling the simulated flame generation module 114 to generate simulated flames; the fire extinguishing equipment 12 is provided with a signal transmitting module 121;

the signal transmitting module 121 is configured to transmit a first sensing signal, and the first sensing module 111 is configured to receive the first sensing signal;

the first control module 112 is configured to determine whether the first sensing signal received by the first sensing module 111 matches a corresponding sensing signal type under the current simulated flame type according to a corresponding relationship between the simulated flame type and the sensing signal type, and if so, adjust the simulated flame generated under the current simulated flame type through the second control module 113.

In this embodiment, the signal emitting module is a laser reflector, and the laser reflector is disposed at a nozzle position of the fire extinguisher. The first sensing module comprises a plurality of groups of laser sensors, the laser frequency bands sensed by different laser sensors are different, and the plurality of groups of laser sensor arrays are arranged on an external shell of the flame simulation equipment. The laser frequency bands emitted by the laser transmitters arranged on each fire extinguisher are different and can be identified by different laser sensors on the shell of the flame simulation equipment. In the actual use process, the opening or closing of each group of laser sensors is controlled through the first control module, for example, the current flame simulation equipment simulates the flame generated under the condition of alcohol ignition, and then the first control module can control the laser sensors which can receive the laser emitted by the laser emitter on the fire extinguisher matched with the fire extinguishing scene and correspond to the frequency band to be opened, and other laser sensors are closed. For example, the fire extinguisher of looks adaptation is the dry powder fire extinguisher, and then the user is taking up the dry powder fire extinguisher and is aimed at when first response module operates, corresponding laser-induced ware just can catch the sensing signal on the first response module, and then adjusts the intensity of a fire through first control module. If other fire extinguishers (referring to fire extinguishers which are not suitable for the alcohol application scene) are aligned with the first sensing module to operate, the first control module does not respond to relevant operations, namely the size of the simulated flame is not adjusted, because the other fire extinguishers cannot emit laser which can be captured by the currently-started laser sensing module. The other situations of combustible ignition and the selection of the fire extinguisher are similar to the above-mentioned modes, and the description is omitted here. In short, whether the first induction signal is responded or not is determined by comparing the type of the corresponding induction signal under the current simulated flame type with the first induction signal, and then the fire extinguishing function is realized.

In certain embodiments, "adjusting, by the second control module, the simulated flames produced under the current simulated flame type" includes: and when the first induction module continuously receives a first induction signal which accords with the corresponding induction signal type under the current simulated flame type in unit time, the size of the simulated flame is reduced according to the echelon. In other embodiments, the method comprises: when the first sensing signal received by the first sensing module is judged not to be in accordance with the corresponding sensing signal type under the current simulated flame type, the size and the color of the simulated flame generated under the current simulated flame type are kept unchanged. By means of the mode, the fire extinguisher selection method is beneficial to a user to select the correct fire extinguisher to extinguish fire according to different application scenes, and the user can learn and memorize related fire-fighting knowledge quickly.

Referring to fig. 18, the second aspect of the present invention further provides a method for interactive control of simulated flames, wherein the method is applied to the system for interactive control of simulated flames according to the first aspect of the present invention, and the system comprises a flame simulating device and a fire extinguishing device; the flame simulation equipment comprises a first induction module, a first control module, a second control module and a simulated flame generation module; the first induction module and the second control module are respectively connected with the first control module, and the second control module is used for controlling the simulated flame generation module to generate simulated flames; the fire extinguishing equipment is provided with a signal transmitting module;

the method comprises the following steps:

firstly, step S101 is performed, in which a signal transmitting module sends out a first sensing signal, and the first sensing module is used for receiving the first sensing signal. The fire extinguishing equipment is preferably a fire extinguisher, the signal transmitting module is a laser transmitter, the laser reflector is arranged at the position of a nozzle of the fire extinguisher, and a user can trigger the laser transmitter by pressing a switch at the nozzle of the fire extinguisher so as to transmit a laser signal of a preset frequency band. The first sensing module preferably comprises a plurality of groups of laser sensors, the laser frequency bands sensed by different laser sensors are different, and the plurality of groups of laser sensor arrays are arranged on an external shell of the flame simulation equipment.

And then, in step S102, the first control module judges whether the first induction signal received by the first induction module conforms to the corresponding induction signal type under the current simulated flame type according to the corresponding relation between the simulated flame type and the induction signal type. If yes, the step S103 is carried out, and the simulated flame generated under the current simulated flame type is adjusted through the second control module.

The simulated flame type can be set according to a preset scene, for example, the simulated flame type can include simulated alcohol ignition, simulated metal ignition, simulated oil and object ignition and the like, under different simulated flame types, the type of the fire extinguisher required to be selected is also different, if the alcohol ignition requires a dry powder fire extinguisher, the metal ignition selects a foam fire extinguisher and the like, so that for different simulated flame types, the first control module can enable the first sensing module to only respond to the laser frequency band emitted by the laser emitter of the correct fire extinguisher by setting the on or off of different laser sensors, if the laser frequency band can be received by the currently-on laser sensor, the type of the fire extinguisher selected by a user is correct, and the size of the current simulated flame can be adjusted by the first control module; otherwise, the type of the fire extinguisher selected by the user is wrong, and the combustion situation of the current simulated flame is kept.

Referring to fig. 1, fig. 2 and fig. 3, a schematic structural diagram of a flame simulation apparatus according to an embodiment of the present invention includes a housing 1, the housing 1 includes a storage cavity 2, the simulation generation module is disposed in the storage cavity, and the flame simulation generation module includes a liquid storage container 21, an atomization device 22, a blowing device 23 and a light source device 24. The liquid storage container 21, the air blowing device 23 and the light source device 24 are all independently arranged, so that the contact of water mist generated in the liquid storage container 21 with the air blowing device 23 and the light source device 24 is isolated, and the service life is longer. The liquid storage container 21 comprises a liquid storage cavity 211, the atomizing device 22 is arranged in the liquid storage cavity 211, and the atomizing device 22 is used for atomizing the liquid in the liquid storage cavity 211; an air guide opening 2111 is formed in the side wall of the liquid storage container 21, the air blowing device 23 is connected with the air guide opening 2111 through an air guide pipe 2112, and the air blowing device 23 is used for blowing air and pressurizing the liquid storage cavity 211. Under the pressurization, the formed simulated flame is more uniform. The housing 1 is provided with a first mist outlet passage 111, and the liquid storage container 21 is provided with a second mist outlet passage 2121 aligned with the first mist outlet passage 111. Atomizing the liquid in the liquid storage cavity 211 by the atomizing device 22 to generate water mist; the air blowing device 23 is used for blowing air to and pressurizing the liquid storage cavity 211 of the liquid storage container 21, so that the water mist in the liquid storage cavity 211 rises and is gathered in the top area of the liquid storage cavity 211, and the smoke is more uniform and concentrated when passing through the second smoke outlet channel 2121; then, under the continuous blowing and pressurizing action of the blowing device 23, the mist is discharged after passing through the second mist outlet passage 2121 and the first mist outlet passage 111 in sequence, and the discharged mist is more uniform, concentrated and continuous. In addition, the light source device 24 is disposed below the first mist outlet channel 111, and the light source device 24 can emit a light source which irradiates toward the first mist outlet channel 111, so that the water mist discharged from the first mist outlet channel 111 interferes with and diffracts the light source emitted by the light source device 24, thereby forming a more realistic simulated flame above the first mist outlet channel 111. The light source device 24 and the liquid storage container 21 are independently arranged, so that the contact between water mist in the liquid storage container 21 and a lamp of the light source device 24 is isolated, and the service life is longer; in addition, because the light source device 24 can emit certain heat when working, the drying of the space in the storage cavity 2 is ensured.

In this embodiment, the specific arrangement of the first mist outlet passage 111 and the second mist outlet passage 2121 is not limited as long as the second mist outlet passage 2121 can be aligned with the first mist outlet passage 111, so that the water mist discharged from the liquid storage container 21 can uniformly, intensively and continuously enter the first mist outlet passage 111 through the second mist outlet passage 2121 and then be discharged from the first mist outlet passage 111. For example, the mist outlet of the second mist outlet passage 2121 may be arranged to abut against the mist inlet of the first mist outlet passage 111; alternatively, as shown in fig. 1, the second mist outlet passage 2121 may extend into the first mist outlet passage 111; or other arrangement modes which can effectively prevent the water mist from being dispersed and not concentrated are adopted. The specific shape of the second mist outlet passage 2121 is not limited as long as the second mist outlet passage 2121 can uniformly and intensively discharge the mist in the liquid reservoir 21. Preferably, the second mist outlet passage 2121 may be disposed in an upper cover of the liquid storage container 21, and the upper cover of the liquid storage container 21 may have a chimney-like structure, and the cross section of the chimney-like structure may be rectangular, circular, oval or other polygonal shapes. For example, as shown in fig. 2 and 3, the upper cover of the liquid storage container 21 is an elongated L-shaped chimney-like structure with a rectangular cross section, but the second mist outlet passage 2121 may be disposed at a middle region of the top of the liquid storage container 21, and is not limited to the position shown in fig. 2 and 3.

In addition, the atomization device 22 in the embodiment is preferably an ultrasonic atomization device 22, the liquid in the liquid storage container 21 is excited by high-frequency ultrasonic vibration to be atomized to form smoke, the formed smoke has no temperature, and a user can directly touch the simulated flame without burning, so that the simulated flame can be experienced in a close range in the use process.

Referring to fig. 4 and 5, in another embodiment, the flame simulation equipment is further provided with a mist guide groove 3, and the mist guide groove 3 is a through groove with an upper opening and a lower opening along the longitudinal direction; the fog guide groove 3 is detachably sleeved on the first fog outlet channel 111, the water fog discharged from the first fog outlet channel 111 can form a rising fog band in the fog guide groove 3, the light source device 24 arranged below the first fog outlet channel 111 emits light beams and irradiates the fog band in the fog guide groove 3 through the first fog outlet channel 111, and therefore colors are attached to the fog band, and simulated flames are formed. The fog guide groove 3 is made of transparent material with good hardness, and the transparent material is glass, acrylic, crystal, transparent plastic or other transparent materials. The transparent fog guide grooves 3 can not only enable the smog to rise uniformly, intensively and continuously in a limited area, but also enable a user to observe closely and experience flames formed in a simulated mode.

Referring to fig. 3, in another embodiment, the liquid storage container 21 includes a cover 213 and a box 213, the cover 213 and the box 213 are detachably connected to form a liquid storage cavity 211; the second mist outlet passage 2121 is provided on the cover 213. The cover 213 and the case 213 can be connected by a snap lock, a snap connection, or other detachable connection, so that the user can conveniently maintain the space or the device inside the liquid storage cavity 211 of the liquid storage container 21.

Referring to fig. 2, in another embodiment, the housing 1 includes a top cover 11 and a base 12, and the top cover 11 and the base 12 are detachably connected to form the storage cavity 2. By detachably connecting the top cover 11 and the base 12, the user can conveniently maintain the space or the device inside the storage cavity 2. As shown in fig. 2, a cover plate 121 may be disposed on an outer sidewall of the base 12, and the cover plate 121 is fixed on the sidewall of the base 12 through a fixing hole; a handle fixing frame 1211 is provided on the cover plate 121 for fixing the handle, thereby facilitating movement and transportation of the flame simulating apparatus.

Referring to FIG. 3, in another embodiment, reservoir 211 includes at least two compartments 2113, with two adjacent compartments 2113 separated by a partition 2114; each compartment 2113 is provided with at least one air guiding opening 2111, each air guiding opening 2111 being connected to a blowing device 23 via a respective air guiding duct 2112. The partition 2114 functions to isolate two adjacent compartments 2113 on either side of the partition 2114 to prevent smoke and air flow within the compartments from interfering with each other. Moreover, the wind power of the air blowing device 23 connected with each compartment 2113 can be controlled, so that the height of the water mist formed in each compartment 2113 is controlled, the formation of smoke bands with different heights in the mist guide groove 3 is facilitated, and the flame formed in a simulated mode has a better visual effect.

In some embodiments, a diversion trench is formed in the bottom of each partition 2114, and the diversion trench is arranged in an inclined manner, so that the collected water in the later-stage liquid storage cavity 211 is conveniently discharged outside. Compartments 2113 are in communication via channels such that the liquids in compartments 2113 are in fluid communication with each other. As shown in fig. 6, two side walls of the liquid storage container 21 are respectively provided with a first fixed support 214 and a second fixed support 215; the height of the first fixing support 214 is greater than that of the second fixing support 215, so that the liquid storage container 21 is disposed in the storage cavity 2 in parallel with respect to the horizontal plane, and the overall structure of the liquid storage container 21 is stable. In addition, a water inlet and a water outlet (not shown) are arranged on the side wall of the liquid storage container 21, and the water inlet and the water outlet are in a closed state when the flame simulation equipment is in a normal working state. Because the guiding gutter slope sets up, the preferred setting of water inlet is in the higher one end of guiding gutter horizontal position, and the delivery port then preferred setting is in the lower one end of guiding gutter horizontal position, when later stage needs the drainage, can accelerate the guiding rivers along guiding gutter flow direction outlet end to make things convenient for the outer row of catchmenting in later stage stock solution chamber 211.

Referring to fig. 6, in other embodiments, a step-up assembly 216 may be further disposed below the first fixing support 214 and the second fixing support 215, and the step-up assembly 216 may be disposed at the bottom of the storage cavity 2 by means of screw connection or welding. Heightening subassembly 216 can set up to two about setting up, is connected with first fixing support 214 and second fixing support 215 respectively for erect whole stock solution container 21 and put the thing chamber 2 in, make the fixed of stock solution container 21 more convenient with the maintenance, guarantee simultaneously that stock solution container 21 does not have positional deviation when fixed, thereby guarantee that second fog passageway 2121 can aim at first fog passageway 111. The heightening component can be set to be a structure with a lateral opening of an accommodating space, so that on one hand, the lower space of the liquid storage container 21 can be made free for installing a power supply or wiring; on the other hand, the accommodating space can be used for accommodating a liquid container, the liquid container is connected with the liquid storage container 21 through a pipeline, and clear water or perfume and other liquids are contained in the liquid container. In addition, in order to make the flame simulation equipment more convenient to move or carry, the shell 1 is made of materials with relatively low hardness and mass, and the heightening component can be made of relatively thick materials, so that the whole mass is not changed greatly on the basis of increasing the stability of the flame simulation equipment, and the flame simulation equipment is relatively light and portable.

Referring to fig. 3, in another embodiment, each compartment 2113 is provided with an atomizing device 22 and a slot 2115 for accommodating the atomizing device 22; atomizing device 22 sets up in draw-in groove 2115, makes things convenient for flame simulation equipment operation in-process to atomizing device 22 fixed to reduce the removal of atomizer in the operation as far as, reduce atomizing device 22's noise to a certain extent, and make things convenient for later stage atomizing device 22's maintenance. The shape of the slot 2115 is rectangular, circular, or other shape, and may be configured according to the particular shape and size of the aerosolization device 22. In other embodiments, the guiding groove at the bottom of each partition 2114 may also be used as the slot 2115 of the atomizing device 22, specifically, the guiding groove is disposed at the inner bottom of the liquid storage cavity 211, and the compartments 2113 are communicated with each other through the guiding groove, so that the liquids in the compartments 2113 can be communicated with each other; and, the guiding gutter is the rectangle, and its width sets up to the size that just in time can block atomizing device 22 to fix atomizing device 22, thereby better protection atomizing device 22 can not appear damaging in the transportation. The atomizing device 22 and the guiding groove can be connected by a snap-fit manner.

In some embodiments, each compartment is also provided with a patch cord outlet 2116 to facilitate connection of the power cord and control cord of the aerosolization apparatus to the power supply apparatus and corresponding control module through the patch cord outlet 2116.

Referring to fig. 2, in another embodiment, the light source device 24 includes a plurality of LED lamps 241, the number of LED lamps 241 is the same as the number of compartments 2113; the storage cavity 2 is internally provided with a fixing support 4 of the LED lamp 241, the LED lamps 241 are arranged on the fixing support 4 at intervals, and the position of each LED lamp 241 corresponds to the position of each compartment 2113. Specifically, as shown in fig. 2 and 3, the projection area of the position where one LED lamp 241 is located is correspondingly distributed within the area of one compartment 2113. The fixing support 4 is provided with a fixing hole for fixing the LED lamp 241, and the fixing hole is a rotary interface (screw) or a bayonet, so that a user can replace the damaged LED lamp 241 conveniently. Preferably, the LED lamp 241 is fixed by a screw, so that any deviation can be avoided when the LED lamp 241 is fixed, the LED lamp is not damaged in the transportation process, and the LED lamp can be replaced by non-professional personnel. In some embodiments, the LED light 241 may also be replaced with a halogen light. In addition, the LED lamps 241 may be operated simultaneously or intermittently in turn.

Referring to FIG. 7, in another embodiment, the flame simulating apparatus further comprises a circuit control system 6, wherein the circuit control system 6 comprises a first control module 61 and a second control module 62; the first control module 62 includes a blower device control module 621, a light source device control module 622, and an atomizing device control module 623; the first control module 61 is electrically connected with the blowing device control module 621, the light source device control module 622 and the atomizing device control module 623 respectively; the blower control module 621 is electrically connected to the blower 23, the light source device control module 622 is electrically connected to the light source device 24, and the atomizer control module 623 is electrically connected to the atomizer 22. The first control module 61 controls the circuit logic operation of each device control module in the first control module 62, and the blower device control module 621, the light source device control module 622 and the atomizing device control module 623 respectively control the operation states of the devices electrically connected thereto, so as to realize automatic start and stop as required. The installation of each device is simpler and more convenient through the modular design, the maintenance of the module is simple, the location and the change of the damaged components are more convenient, the internal connecting wires are not complicated any more, the connecting wires between the modules are clear at a glance, and the installation and the maintenance of the components inside the flame simulation equipment shell 1 are convenient.

Specifically, the first control module may implement the adjustment of the simulated flame size by any one or more of powering down/turning off the blower device control module 621, the light source device control module 622, and the atomizing device control module 62. Meanwhile, by adjusting the light intensity and the light emitting color of the light source device control module 622, the condition for simulating the burning intensity of the flame is realized, that is, the flame color adjustment is realized as described above.

Specifically, the blower driving circuit is shown in fig. 9. When the signal IO _ FS is at a high level, the MOS transistor AO3400A is turned on, the blower 23 operates, and the output frequency of the signal IO _ FS is controlled so that the blower 23 obtains outputs of different powers. The resistor R11 is a current-limiting resistor to prevent the MOS transistor AO3400A from being damaged due to excessive input current, and the resistor R12 is a pull-down resistor to keep the G pole of the MOS transistor AO3400A at a low level when the G pole does not work, so that malfunction caused by interference of other signals is isolated. The driving circuit of the blower is simpler and more stable by using the MOS tube AO3400A, the adjustable output power range of the MOS tube AO3400A is larger, and no sound is generated when the relay works.

Specifically, the light source device driving circuit is shown in fig. 10. When the signal IO _ LED1 is at a high level, the triode Q1 is conducted, so that the zero-cross trigger double-silicon output optocoupler MOC3061 is triggered and conducted, the MOC3061 drives the bidirectional thyristor BTA20-600 to be conducted, the LED lamp 241 is lightened, and the arrow indicates the current direction when the bidirectional thyristor BTA20-600 is conducted. The resistor R1 enables the triode Q1 to work in a switch state, the resistor R2 has a current limiting effect, so that the current input to the MOC3061 is smaller than 15mA, the resistors R3 and R4 are current limiting resistors for triggering the bidirectional thyristor BTA20-600, and in addition, the resistor R5 and the capacitor C1 form a surge absorption circuit to prevent surge voltage from damaging the bidirectional thyristor BTA 20-600. The zero-cross trigger bidirectional silicon output optocoupler MOC3061 and the bidirectional silicon controlled rectifier BTA20-600 are used for enabling a driving circuit to be simpler and more stable, and the strong current and the weak current are separated, so that no sound is generated when the relay works.

Specifically, the atomizer driving circuit is shown in fig. 11. When the signal IO _ WuHuaQi is at a high level, the MOS transistor AO3400A is turned on, the atomizer 22 operates, and the output frequency of the signal IO _ FS is controlled so that the atomizer 22 obtains outputs of different powers. The resistor R13 is a current-limiting resistor to prevent the MOS transistor AO3400A from being damaged due to excessive input current, and the resistor R14 is a pull-down resistor to keep the G pole of the MOS transistor AO3400A at a low level when the G pole does not work, so that malfunction caused by interference of other signals is isolated. The driving circuit of the atomization device is simpler and more stable by using the MOS tube AO3400A, the adjustable output power range of the MOS tube AO3400A is larger, and no sound is generated when a relay works.

Referring to fig. 6, in another embodiment, a speaker 7 is further disposed in the storage chamber 2 for emitting a sound simulating the burning of flames. The quantity of speaker 7 is two, sets up respectively in stock solution container 21's the left and right sides for the sound that sends has more the stereoeffect, increases the simulation of audio in the effect of simulated flame, makes simulated flame more vivid, also can increase partly group to the perception on the auditory sense when flame burns, and not only the impression that stops in the vision, thereby has richened flame simulation equipment's experience effect. The first control module 62 further includes an audio control module 624, the first control module 61 is electrically connected to the audio control module 624, and the audio control module 624 is electrically connected to the speaker 7, and is configured to control an operating state of the speaker 7, and implement automatic start and stop as required.

Specifically, as shown in fig. 12, the speaker driving circuit uses a chip HT 6872; the capacitor C22 is a voltage-stabilizing filter capacitor, so that the stability of a power supply of the HT6872 chip is ensured when the chip works; the resistor R18 is a pull-down resistor, so that the chip HT6872 is kept in a closed state when no signal is input; SP 1-and SP1+ are connected with the positive and negative electrodes of the loudspeaker and are used for driving the loudspeaker; MP3_ LEFT is an audio drive signal; the capacitor C21 and the resistor R20 form an RC high-pass filter.

Referring to fig. 3 and 6, in another embodiment, a liquid level meter 5 is further disposed in the liquid storage cavity 211 of the liquid storage container 21, the liquid level meter 5 includes a first liquid level meter 51 and a second liquid level meter 52, and a horizontal height of the first liquid level meter 51 is higher than a horizontal height of the second liquid level meter 52. The first liquid level meter 51 and the second liquid level meter 52 are respectively used for monitoring the high and low liquid level conditions in the liquid storage cavity 211. The first control module 62 further includes a gauge control module 625, the gauge control module 625 being electrically connected to the first gauge 51 and the second gauge 52, respectively. In the present embodiment, the first level gauge 51 and the second level gauge 52 are non-contact level sensors, such as laser level sensors, ultrasonic level sensors, photoelectric level sensors, and the like. The non-contact liquid level sensor does not need to be in direct contact with liquid, cannot be corroded by corrosive liquid such as strong acid, strong alkali and the like, and cannot be influenced by water scales or other impurities; simultaneously, for using contact level sensor, non-contact level sensor need not do waterproof sealing and handles, and long service life and easy the change are maintained, do not occupy the stock solution chamber 211 volume of stock solution container 21 simultaneously, provide bigger space for installing other structures and functions in the stock solution chamber 211.

Specifically, the detection water inlet and outlet control circuit of the liquid level meter is shown in fig. 13, an interface P1 and an interface P2 are liquid level meter interfaces, and the type of the interfaces is XH 2.54-4P; the liquid level meter is a non-contact liquid level detection sensor XKC-Y25-NPN; the resistor R1 and the resistor R2 are current limiting resistors, so that the current transmitted by the detection signal of the liquid level detection sensor to the first control module 61 is reduced, and the interface 6 is connected with the interface module 6 (the atomization device control module 623, the blowing device control module 621, the light source device control module 622, and the liquid level meter control module 625 circuit switching module).

Referring to fig. 6, in another embodiment, a water inlet motor 8 is further disposed in the storage cavity 2, and the water inlet motor 8 is connected to the liquid storage container 21 through a water inlet pipe, and is used for delivering a required liquid from an external liquid storage device to the liquid storage cavity 211 of the liquid storage container 21. First control module 62 still includes into water motor control module 626, and into water motor control module 626 is connected with into water motor 8 electricity for control into the running state of water motor 8, realize automatic opening as required and stop.

Specifically, as shown in fig. 14, when the signal IO _ JinShui is at a high level, the MOS transistor AO3400A is turned on, the water inlet motor 8 operates, and the output frequency of the signal IO _ JinShui is controlled to enable the water inlet motor 8 to obtain outputs of different powers. The resistor R3 is a current-limiting resistor to prevent the MOS transistor AO3400A from being damaged due to excessive input current, and the resistor R4 is a pull-down resistor to keep the G pole of the MOS transistor AO3400A at a low level when the G pole does not work, so that malfunction caused by interference of other signals is isolated. The water inlet driving circuit is simpler and more stable by using the MOS tube AO3400A, the adjustable output power range of the MOS tube AO3400A is larger, and no sound is generated when the relay works.

In addition, in other embodiments, a water outlet motor 9 is further disposed in the storage cavity 2, and the water outlet motor 9 is connected to the liquid storage container 21 through a water outlet pipe, and is used for discharging liquid from the liquid storage cavity 211 of the liquid storage container 21 to the outside. The first control module 62 further comprises a water outlet motor control module 627, and the water outlet motor control module is connected with the water outlet motor 627 and used for controlling the running state of the water outlet motor 9 and realizing automatic start and stop as required.

Specifically, as shown in fig. 15, when the signal IO _ ChuShui is at a high level, the MOS transistor AO3400A is turned on, the effluent motor 9 operates, and the output frequency of the signal IO _ ChuShui is controlled to enable the effluent motor 9 to obtain outputs of different powers. The resistor R5 is a current-limiting resistor to prevent the MOS transistor AO3400A from being damaged due to excessive input current, and the resistor R6 is a pull-down resistor to keep the G pole of the MOS transistor AO3400A at a low level when the G pole does not work, so that malfunction caused by interference of other signals is isolated. The water drainage driving circuit is simpler and more stable by using the MOS tube AO3400A, the adjustable output power range of the MOS tube AO3400A is larger, and no sound is generated when the relay works.

In another embodiment, the circuit control system 6 further includes a wireless communication module 63, the wireless communication module 63 is connected to the mobile terminal in a communication manner, and the wireless communication module 63 is electrically connected to the first control module 61. The wireless communication module 63 is used for receiving a remote control signal sent by the mobile terminal and transmitting the signal to the first control module 61. The wireless communication module 63 includes a 3G/4G/5G wireless communication module, a WIFI module, an NFC module, a UMB module, a CDMA module, a GSM module, a bluetooth module, and a ZIGBEE communication module, and various modules can be used in combination. GSM and CDMA are two communication systems of mobile operators in China, and can be connected to any covered place of corresponding operators conveniently through GSM modules and CDMA modules, where GSM modules and CDMA modules also include their variants, for example, GPRS modules are one of GSM modules, CDMA1X modules are one of CDMA modules, and there are corresponding 3G, 4G and 5G versions at present. The bluetooth module, the ZigBee module, the WiFi module, the UMB module, and the NFC module are currently popular short-range wireless communication modules and are not limited to the line-of-sight range. A compromise mode may also be used, where wireless communication is used for communication as a whole, wired communication is used locally, and then remote control is received via wireless communication. The signal receiving circuit of the wireless communication module 63 is shown in fig. 16, and uses an infrared receiving chip VS 1838B; the capacitor C11 is a voltage-stabilizing filter capacitor, so that the stability of a power supply is ensured when the VS1838B chip works; the resistor R2 is a pull-up resistor, and stabilizes the high-low level of the received signal of VS1838B between 0V and 3.3V.

In fig. 9 to 15, terms of respective circuit devices are explained as follows: in fig. 9, "FengJi" represents a blower, i.e., the aforementioned blower device; in FIG. 10, "JDQ" represents a relay of type JQC-3FF-005-1ZS, and "GDOHQ" represents a photocoupler of type PC 817B; in fig. 11, "WuHuaQi" represents a nebulizer, i.e., the aforementioned nebulizing device; in fig. 13, 14, and 15, "GaoShuiWei" represents the high level gauge, i.e., the aforementioned first gauge, "dihuiwei" represents the low level gauge, i.e., the aforementioned second gauge, "JinShui" represents the water inlet motor, and "ChuShui" represents the water outlet motor.

Referring to fig. 6, in the above embodiment, the circuit control system 6 further includes a power module 10, and the power module 10 is electrically connected to the first control module 61. The power supply required by the flame simulation equipment during working is introduced into the power supply module 10 through a power line, and the required electric quantity is provided for each electric device and each control module through the power supply module 10.

Preferably, the first control module 61, the first control module 62, the wireless communication module 63 and the power module 10 are integrated on a same circuit board (not shown), and are mounted on the outer side wall of the base 12 of the liquid storage container 21 through a cover plate 121.

Referring to fig. 8, in some embodiments, a plurality of sets of laser signal detection modules 101 are further disposed on the housing 1, and each laser signal detection module 101 is electrically connected to the first control module 61 respectively for detecting a laser signal emitted by the second device. The second device is preferably a fire extinguisher. As shown in fig. 8, a plurality of sets of laser signal detection modules 101 may be disposed on the top cover 11 of the housing 1. For example, in the application scenario of simulating the practice of fire fighting, a user can hold a fire extinguisher by hand to align a nozzle (the position of the nozzle is provided with a laser emitting module) of the fire extinguisher with the laser signal detection module 101 on the housing 1, when the user presses a light emitting button, a laser signal emitted by the fire extinguisher is captured by the laser signal detection module 101 on the housing 1, and the laser signal detection module 101 immediately sends a feedback signal to the first control module 61, so that the first control module 61 gradually stops working by controlling an atomizer, a blower, a light source module and the like, thereby simulating the process of fire fighting. Preferably, the laser signal wave band detected by the laser signal detection module 101 can be adjusted according to the needs of the actual application scene, the nozzles of the fire extinguishers of different types may emit laser signals of different wave bands, when the emitted laser signals are not matched with the currently set detection laser signals, it is indicated that the operator is using the wrong fire extinguisher to extinguish a fire, and at this time, the first control module 61 does not respond to the feedback signal, that is, the simulated flame is not extinguished. Through above-mentioned scheme, can effectively simulate the application scene of putting out a fire, promote user's operating specification, strengthen its fire prevention consciousness.

Referring to fig. 8, in some embodiments, an LED display 102 is further disposed on the side of the base 12 of the housing 1, and the LED display 102 is used for displaying the operation status of the flame simulation apparatus, including the water level condition of the liquid storage container 21, prompting information, parameters (color, brightness, height, etc.) of the simulated flames, the process profile of the formation of the simulated flames, the process profile of the simulated drilling fire, and the like. The first control module 62 further includes an LED display control module 628, and the LED display control module 628 is electrically connected to the LED display 102 and the first control module 61, respectively, for controlling the display content of the LED display 102.

Next, the operation of the flame simulating apparatus will be described.

1. And (3) water adding process: during operation of the flame simulating apparatus, the first level gauge 51 and the second level gauge 52 monitor the liquid level condition in the liquid storage cavity 211 in real time, and transmit corresponding high/low liquid level signals to the first control module 61 through the liquid level gauge control module 625. After the first control module 61 receives the low liquid level signal, the loudspeaker is controlled to send out a water-free prompt sound in the liquid storage container 21 to remind a user of adding water; the first control module 61 controls the power module to automatically power off without any operation by the user for a period of time. Specifically, the user sends a water adding signal through a remote control tool (a mobile terminal, an infrared remote controller, etc.), the wireless communication module 63 receives the water adding signal and transmits the water adding signal to the first control module 61, the first control module 61 receives the water adding signal and then sends a water pumping signal to the water inlet motor control module 626, and the water inlet motor control module 626 controls the water inlet motor 8 to pump water. When the liquid level height reaches the position of the first liquid level meter 51 in the liquid storage cavity 211, the first liquid level meter 51 transmits a high liquid level signal to the first control module 61 through the liquid level meter control module 625, the first control module 61 receives the high liquid level signal and then sends a water inlet stopping signal to the water inlet motor control module 626, so as to control the water inlet motor 8 to stop pumping water, and meanwhile, the first control module 61 controls the loudspeaker to send out a prompt sound that the liquid storage container 21 is filled with water.

2. And (3) a flame forming process: the user sends a starting signal through the remote control tool, the wireless communication module 63 receives the starting signal and then transmits the starting signal to the first control module 61, and the first control module 61 receives the starting signal and then sends a corresponding control signal to the atomizing device control module 623 to control the atomizing device 22 to start working. The atomization device 22 is vibrated by high-frequency ultrasonic waves to excite the liquid in the liquid storage container 21 to be atomized to form smoke, and since no external pressure forms water mist to be suspended in the water mist cavity, when the concentration of the water mist reaches a preset concentration, the first control module 61 sends corresponding control signals to the air blowing device control module 621, the light source device control module 622 and the audio control module 624 to respectively control the air blowing device 23, the light source device 24 and the loudspeaker to start working. The air blower 23 blows the outside air into the liquid storage cavity 211 through the air guide tube 2112, at this time, the pressure in the liquid storage cavity 211 rises, and the pressure in the liquid storage cavity 211 rises to force the water mist to rise, and the water mist enters the mist guide groove 3 after passing through the second mist outlet channel 2121 and the first mist outlet channel 111 in sequence; since the pressure inside the liquid storage cavity 211 is higher than the pressure in the outside air, the water mist discharged from the first mist outlet channel 111 is forced to continuously rise, and a continuously rising mist belt is formed in the mist guide groove 3. The light of the light source device 24 irradiates on the smoke band which continuously rises in the smoke guide groove 3 through the first smoke outlet channel 111, colors are attached to the smoke band, a vivid flame effect is formed, and at the moment, the loudspeaker emits the sound of simulating flame combustion, so that the simulated flame is more vivid.

3. And (3) flame regulation process:

(1) adjusting the flame size: the user sends out a flame size adjusting signal through the remote control tool, the wireless communication module 63 receives the flame size adjusting signal and then transmits the flame size adjusting signal to the first control module 61, and the first control module 61 receives the flame size adjusting signal and then sends a corresponding control signal to the atomizing device control module 623 to control the atomizing device 22 to output corresponding power. Due to the change of the output power of the atomization device 22, the concentration of the water mist in the liquid storage container 21 changes, and further the concentration of the smoke band continuously rising in the mist guide groove 3 changes, and at the moment, the size of the flame formed by the light beam emitted by the light source device 24 irradiating on the rising smoke band changes. The user controls the size of the simulated flame through the remote control tool so as to achieve the size of the simulated flame required by the user. In addition, the user can also send different flame size adjusting instructions according to the number of the specific atomization devices 22; different atomizing devices 22 output different powers according to different received adjusting signals, so that the concentration of water mist formed by excitation of each atomizing device 22 is different, and then flames of different sizes are formed in the mist guide groove 3.

(2) Adjusting the flame height: the user sends out the flame height adjusting signal through the remote control tool, the wireless communication module 63 receives the flame height adjusting signal and then transmits the flame height adjusting signal to the first control module 61, and after receiving the flame height adjusting signal, the first control module 61 sends a corresponding control signal to the air blowing device control module 621 so as to control the air blowing device 23 to output corresponding power. Due to the change of the output power of the blower 23, the pressure inside the liquid storage container 21 is changed, so that the rising height of the water mist discharged from the first mist outlet channel 111 is changed, and the height of the flame formed in the mist guide groove 3 is correspondingly changed. The user controls the height of the simulated flame through the remote control tool so as to achieve the height of the simulated flame required by the user. In addition, the user can send out different flame height adjusting instructions according to the number of the specific air blowing devices 23; different blast devices 23 output different powers according to different received adjusting signals, so that the pressure in each compartment 2113 of the liquid storage container 21 is different, flames with different heights are formed in the mist guide grooves 3, and the formed simulated flames have a visual effect.

(3) Adjusting the flame color: the user sends out a flame color adjusting signal through the remote control tool, the wireless communication module 63 receives the flame color adjusting signal and transmits the flame color adjusting signal to the first control module 61, and the first control module 61 receives the flame color adjusting signal and then sends a corresponding control signal to the light source device control module 622 to control the light source device 24 to output a light beam with a corresponding color. Because the color of the light beam emitted by the light source device 24 changes, the light beam irradiates the smoke band which continuously rises in the fog guide groove 3, so that the color of the rising smoke band changes, and the color of the flame which is simulated to form changes. The user controls the color of the simulated flame through the remote control tool so as to achieve the color of the simulated flame required by the user. In addition, the user can also send out different flame color adjusting instructions according to the number of the specific LED lamps 241 (or halogen lamps) of the light source device 24; the different LED lamps 241 emit light beams of different colors according to the received different adjustment signals, so that multicolored flames are formed in the fog guide grooves 3.

(4) Adjusting the flame brightness: the user sends out a flame brightness adjusting signal through the remote control tool, the wireless communication module 63 receives the flame brightness adjusting signal and transmits the flame brightness adjusting signal to the first control module 61, and the first control module 61 receives the flame brightness adjusting signal and then sends a corresponding control signal to the light source device control module 622 to control the light source device 24 to output corresponding power. Because the power output by the light source device 24 is changed, the brightness of the light beam emitted by the light source device 24 is changed, the light beam irradiates the smoke zone which continuously rises in the smoke guide groove 3, and further the brightness of the rising smoke zone is changed, so that the brightness of the simulated flame is changed. The user controls the brightness of the simulated flame through the remote control tool so as to achieve the brightness of the simulated flame required by the user. In addition, the user can also send out different flame brightness adjusting instructions according to the number of the specific LED lamps 241 (or halogen lamps) of the light source device 24; different LED lamps 241 emit light beams with different brightness according to different received adjusting signals, so that flames with alternate light and shade are formed in the fog guide groove 3.

(5) Adjusting the sound volume of flame combustion: the user sends a volume adjustment signal through the remote control tool, the wireless communication module 63 receives the volume adjustment signal and transmits the volume adjustment signal to the first control module 61, and the first control module 61 receives the volume adjustment signal and then sends a corresponding control signal to the audio control module 624 to control the speaker to output corresponding power. Due to the change of the power of the loudspeaker, the sound emitted by the loudspeaker is changed, and a user controls the volume of the simulated flame combustion sound emitted by the loudspeaker through a remote control tool, adjusts the background volume of the flame combustion and can also adjust the background volume to be mute.

Compared with the prior art, the liquid in the liquid storage cavity 211 is atomized by the atomization device 22 to generate water mist; the air blowing device 23 blows air to the liquid storage cavity 211 of the liquid storage container 21 for pressurization, so that the water mist in the liquid storage cavity 211 rises and is discharged after passing through the second mist outlet channel 2121 and the first mist outlet channel 111 in sequence. Meanwhile, the light source device 24 disposed below the first mist outlet channel 111 emits a light source which irradiates toward the first mist outlet channel 111, so that the water mist discharged from the first mist outlet channel 111 interferes with and diffracts the light source emitted by the light source device 24, and a simulated flame is formed above the first mist outlet channel 111 (the mist guide groove 3). By adopting the technical scheme, the liquid storage container 21, the air blowing device 23 and the light source device 24 are all independently arranged, so that the contact of water mist generated in the liquid storage container 21 with the air blowing device 23 and the light source device 24 is isolated, and the service life is longer; the air blowing device 23 is used for blowing air and pressurizing the liquid storage cavity 211 of the liquid storage container 21, and the second mist outlet channel 2121 formed in the liquid storage container 21, the first mist outlet channel 111 formed in the shell 1 and the mist guide groove 3 sleeved on the first mist outlet channel 111 are combined, so that the discharged water mist is more uniform, concentrated and continuous, and the formed simulated flame is more vivid; two adjacent compartments 2113 on both sides of the partition 2114 are isolated by the partition 2114 to block smoke and air flow in the compartments and prevent the smoke and air flow from affecting each other, so that the formed flame can be controlled and regulated in different areas; by controlling the atomizing device 22 in each compartment 2113, the concentration of the mist formed in each compartment 2113 is controlled, so that mist bands with different concentrations are formed in the mist guide groove 3; the wind power of the air blowing device 23 connected with each compartment 2113 is controlled, so that the height of the water mist formed in each compartment 2113 is controlled, and the formation of smoke bands with different heights in the mist guide groove 3 is facilitated; by controlling the brightness and the color of the light beam emitted by the LED lamp 241 corresponding to the position of each compartment 2113, a gorgeous and bright-dark flame is formed in the mist guide groove 3; the output power of the loudspeakers at the left side and the right side of the liquid storage container 21 is controlled, so that the sound volume of the combustion sound of the simulated flame is adjusted, and the simulation of sound effect is increased on the effect of the simulated flame, so that the simulated flame is more vivid. Therefore, the flame formed by the simulation of the flame simulation equipment provided by the application has the randomness and irregularity of smoke, and the simulated flame is more real, vivid and natural, and is simple and convenient to operate, simple in structure, practical and economical. In addition, the wireless control module can realize remote operation control, so that the user can operate the wireless control module simply and conveniently; by utilizing the modular design, a user can maintain and replace the internal components of the flame simulation equipment more simply and conveniently.

In the description of the present application, the structures, proportions, sizes, and other elements shown in the drawings are only used for understanding and reading the contents disclosed in the specification, and are not intended to limit the conditions under which the present invention can be implemented, so they have no technical significance, and any structural modifications, changes in proportions, or adjustments in size, without affecting the efficacy and attainment of the same, should still fall within the scope of the technical content disclosed in the present invention.

In the present invention, unless otherwise specified and limited, "above" or "below" a first feature may include the first and second features being in direct contact, and may also include the first and second features not being in direct contact but being in contact with each other through another feature therebetween. Also, the first feature being "above," "below," and "above" the second feature includes the first feature being directly above and obliquely above the second feature, or simply an elevation which indicates a level of the first feature being higher than an elevation of the second feature. The first feature being "above", "below" and "beneath" the second feature includes the first feature being directly below or obliquely below the second feature, or merely means that the first feature is at a lower level than the second feature.

In the description of the present application, unless explicitly stated or limited otherwise, the terms "first", "second", and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance; the term "plurality" means two or more unless otherwise specified or indicated; the terms "connected," "fixed," and the like are to be construed broadly and may, for example, be fixedly connected, detachably connected, integrally connected, or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In addition to the foregoing, it should be noted that reference throughout this specification to "one embodiment," "another embodiment," "certain embodiments," or the like, means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment described generally herein. The appearances of the same phrase in various places in the specification are not necessarily all referring to the same embodiment. Further, when a particular feature, structure, or characteristic is described in connection with any embodiment, it is submitted that it is within the scope of the invention to effect such feature, structure, or characteristic in connection with other embodiments.

Finally, it should be noted that, although the above embodiments have been described herein, the scope of the present invention is not limited thereby. Therefore, based on the innovative concepts of the present invention, the technical solutions of the present invention can be directly or indirectly applied to other related technical fields by making changes and modifications to the embodiments described herein, or by using equivalent structures or equivalent processes performed in the content of the present specification and the attached drawings, which are included in the scope of the present invention.

Claims (10)

1. An interactive control system for simulating flames, which is characterized in that the system comprises a flame simulating device and a fire extinguishing device; the flame simulation equipment comprises a first induction module, a first control module, a second control module and a simulated flame generation module; the first induction module and the second control module are respectively connected with the first control module, and the second control module is used for controlling the simulated flame generation module to generate simulated flames; the fire extinguishing equipment is provided with a signal transmitting module;

the signal transmitting module is used for transmitting a first induction signal, and the first induction module is used for receiving the first induction signal;

the first control module is used for judging whether the first induction signal received by the first induction module accords with the corresponding induction signal type under the current simulated flame type according to the corresponding relation between the simulated flame type and the induction signal type, and if so, the simulated flame generated under the current simulated flame type is adjusted through the second control module.

2. The interactive control system of simulated flames according to claim 1, wherein adjusting, by the second control module, simulated flames produced under a current simulated flame type comprises:

and when the first induction module continuously receives a first induction signal which accords with the corresponding induction signal type under the current simulated flame type in unit time, the size of the simulated flame is reduced according to the echelon.

3. The interactive control system for simulating flames according to claim 1, wherein the method comprises:

when the first sensing signal received by the first sensing module is judged not to be in accordance with the corresponding sensing signal type under the current simulated flame type, the size and the color of the simulated flame generated under the current simulated flame type are kept unchanged.

4. The interactive control system for simulating flames according to claim 1, wherein the signal emitting module is a laser emitter, and the laser emitter is arranged at a nozzle position of a fire extinguisher.

5. The interactive control system for simulating flames according to claim 1, wherein the first sensing module comprises a plurality of groups of laser sensors, the laser frequency bands sensed by different laser sensors are different, and the plurality of groups of laser sensor arrays are arranged on an outer shell of the flame simulation device.

6. The interactive control system for simulating flames according to any one of claims 1 to 5, wherein the flame simulation device comprises a housing, the housing comprises a storage cavity, the simulation generation module is arranged in the storage cavity, and the flame simulation generation module comprises a liquid storage container, an atomization device, a blowing device and a light source device;

the liquid storage container comprises a liquid storage cavity, the atomization device is arranged in the liquid storage cavity, and the atomization device is used for atomizing liquid in the liquid storage cavity;

the side wall of the liquid storage container is provided with an air guide opening, the air blowing device is connected with the air guide opening through an air guide pipe, and the air blowing device is used for blowing air and pressurizing the liquid storage cavity;

a first mist outlet channel is formed in the shell, and a second mist outlet channel aligned with the first mist outlet channel is formed in the liquid storage container;

the light source device is arranged below the first fog outlet channel and can emit light sources irradiating towards the first fog outlet channel.

7. The interactive control system for simulating flames according to claim 6, further comprising a fog guide groove, wherein the fog guide groove is a through groove which is vertically opened in the longitudinal direction; the fog guide groove is detachably sleeved on the first fog outlet channel.

8. The interactive control system for simulating flames according to claim 6,

the second control module comprises a blowing device control module, a light source device control module and an atomization device control module; the first control module is respectively and electrically connected with the air blowing device control module, the light source device control module and the atomization device control module;

the air blowing device control module is electrically connected with the air blowing device, the light source device control module is electrically connected with the light source device, and the atomization device control module is electrically connected with the atomization device.

9. The interactive control system for simulating flames according to claim 8, wherein a speaker is further disposed in the storage chamber, and the second control module further comprises an audio control module;

the first control module is electrically connected with the audio control module, and the audio control module is electrically connected with the loudspeaker.

10. A method for interactive control of simulated flames, wherein the method is applied to an interactive control system for simulated flames according to any one of claims 1 to 9, and the system comprises a flame simulating device and a fire extinguishing device; the flame simulation equipment comprises a first induction module, a first control module, a second control module and a simulated flame generation module; the first induction module and the second control module are respectively connected with the first control module, and the second control module is used for controlling the simulated flame generation module to generate simulated flames; the fire extinguishing equipment is provided with a signal transmitting module;

the method comprises the following steps:

the signal transmitting module sends out a first induction signal, and the first induction module is used for receiving the first induction signal;

the first control module judges whether the first induction signal received by the first induction module accords with the corresponding induction signal type under the current simulated flame type according to the corresponding relation between the simulated flame type and the induction signal type, and if so, the second control module adjusts the simulated flame generated under the current simulated flame type.

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