CN112923320A - Mars simulation device and simulation electric fireplace - Google Patents

Abstract

The invention relates to a mars simulation device, which comprises a light source, a reflecting piece, a rotary reflecting component and an imaging plate, wherein the light source is arranged on the light source; the light source emits a first parallel light beam after being electrified; the light reflecting piece is fixedly arranged in the first parallel light beam path, a plurality of first light reflecting sheets are arranged on the light reflecting piece, and the first parallel light beams are reflected by the first light reflecting sheets to form a plurality of second parallel light beams with different reflection angles; the rotary light reflecting assembly comprises a rotating shaft and a plurality of second light reflecting sheets arranged on the rotating shaft, and the second light reflecting sheets sequentially and circularly interfere in the path of the second parallel light beams along with the rotation of the rotating shaft and reflect a plurality of third parallel light beams; the imaging plate is fixedly arranged in the path of the third parallel light beams from the plurality of strips. The invention also provides a simulated electric fireplace. The invention can simulate the effect of the Mars jump of the vertical movement and improve the reality and the stereoscopic impression of the combustion of the simulation fuel.

Description

Mars simulation device and simulation electric fireplace

Technical Field

The invention relates to the technical field of simulation electric fireplaces, in particular to a Mars simulation device capable of simulating Mars jumping and an electric fireplace.

Background

The simulated electric fireplace, as a decoration device fused with modern optical principles, has more outstanding decoration effect and the widest stream, takes electric energy as energy, produces two-dimensional or three-dimensional flame by means of light reflection, is matched with simulated charcoal, has no open fire, simultaneously produces the visual effect of simulating flame combustion, and has vivid effect. Compared with the traditional fireplace, the electric fireplace can not generate smoke dust, smell and noise during combustion, not only can save cost, but also can bring elegant and comfortable ornamental effect and enjoy warmth and comfort brought by the electric fireplace.

In the prior art, in order to make the effect of the simulation fuel vivid, it is a common practice to arrange a light source on the bottom or the side wall of the simulation fuel for illuminating the simulation fuel to generate the visual effect of combustion. However, this method cannot show the real effect of actual burning, for example, the spark splashed during burning of charcoal cannot be reflected, and the picture is stiff, resulting in insufficient reality and stereoscopic impression.

Disclosure of Invention

The first purpose of the present invention is to overcome the disadvantages of the prior art, and to provide a spark simulation device, which can simulate the effect of spark fluttering.

The second purpose of the invention is to provide a simulated electric fireplace provided with the Mars simulation device.

The invention is realized by the following technical scheme: a mars simulation device comprises a light source, a reflecting piece, a rotary reflecting component and an imaging plate; the light source emits a first parallel light beam after being electrified; the light reflecting piece is fixedly arranged in the first parallel light beam path, a plurality of first light reflecting sheets are arranged on the light reflecting piece, and the first parallel light beams are reflected by the first light reflecting sheets to form a plurality of second parallel light beams with different reflection angles; the rotary light reflecting assembly comprises a rotating shaft and a plurality of second light reflecting sheets arranged on the rotating shaft, and the second light reflecting sheets sequentially and circularly interfere in the path of the second parallel light beams along with the rotation of the rotating shaft and reflect a plurality of third parallel light beams; the imaging plate is fixedly arranged in the path of the third parallel light beams from the plurality of strips.

Compared with the prior art, the invention utilizes the light beam emitted by the light source to irradiate the light reflecting piece provided with the plurality of light reflecting sheets to form a plurality of small light spots, the light reflecting piece reflects the small light spots to the rotary light reflecting component, and then the small light spots are reflected to the imaging plate by the rotary light reflecting component to be in a spark shape, meanwhile, the rotary light reflecting component continuously rotates, and the light spots irradiated to the imaging plate can change in shape and position along with the change of the rotating angle, so that the dim light spots are formed on the imaging plate, the effect of simulating the up-and-down movement of the spark jump generated by the burning of charcoal is achieved, and the sense of reality and the stereoscopic impression of the burning of the simulation fuel are improved.

Furthermore, the surface of the light reflecting piece irradiated by the first parallel light beams is a curved surface, and the plurality of first light reflecting pieces are arranged on the curved surface.

Further, the light reflecting piece is a revolution body, and a bus of the revolution body is a unimodal curve section; the rotation axis of the revolution body is perpendicular to the first parallel light beam.

Furthermore, the first reflective sheets are arranged in a circle along the circumferential direction of the revolution body and are closely arranged in a plurality of circles along the axis of the revolution body. The light beam irradiates the reflector, and because the surface of the reflector is a curved surface, the angles of each reflector arranged on the surface of the reflector are different, and therefore, a plurality of small light spots with different reflection angles can be generated. Meanwhile, the outward diffused reflection light can be generated in the horizontal direction, so that the reflection range in the horizontal direction is enlarged; at the same time, the vertical direction also produces a varying reflection angle.

Further, the light source is at least one laser diode. The light emitted by the laser diode is concentrated, and the generated small light spot is brighter.

Further, the rotary reflecting component also comprises a motor and two clamping seats; the motor is fixedly arranged; one end of the rotating shaft is coaxially connected with an output shaft of the motor; the two clamping seats are alternately arranged on the shaft body of the rotating shaft in a penetrating way; the plurality of second light reflecting pieces are arranged at intervals along the circumferential direction of the rotating shaft, and two ends of each second light reflecting piece are respectively clamped in the two clamping seats. The small light spots formed by the light reflecting pieces are reflected to the imaging plate for imaging through the second regularly arranged light reflecting pieces, and the shapes of the small light spots can still be kept.

Furthermore, each second light reflecting sheet is in a rectangular flat plate shape, and a plurality of square tooth-shaped light reflecting parts are formed on the second light reflecting sheet.

Furthermore, the square tooth-shaped light reflecting parts on two adjacent second light reflecting pieces which are arranged at intervals along the axial direction are staggered with each other.

Further, the simulation fuel and the simulation fuel light source are further included, and the simulation fuel is arranged in front of the imaging plate.

In order to achieve the second purpose, the invention is realized by the following technical scheme:

a simulation electric fireplace comprises a shell, wherein a window communicated with an inner cavity of the shell is arranged on the front side surface of the shell, and the spark simulation device is arranged in the inner cavity of the shell.

For a better understanding and practice, the invention is described in detail below with reference to the accompanying drawings.

Drawings

FIG. 1 is a schematic view of the overall structure of a simulated electric fireplace in embodiment 1 of the present invention.

Fig. 2 is a schematic view of the internal structure of the simulated electric fireplace in embodiment 1 of the present invention.

Fig. 3 is a schematic structural diagram of the reflector of the present invention.

FIG. 4 is a schematic view of the whole structure of the simulated electric fireplace in embodiment 2 of the present invention.

Wherein the reference numerals are: 10-shell, 20-simulation fuel, 21-simulation fuel light source, 31-light source, 32-light reflecting piece, 32 a-first light reflecting piece, 33-rotary light reflecting component, 33 a-first light reflecting piece, 34-imaging plate, 34 a-light transmitting plate, 331-rotating shaft, 332-motor, 333-clamping seat, 334-second light reflecting piece and 334 a-square tooth-shaped light reflecting part.

Detailed Description

Example 1

The technical scheme of the invention is described in detail in the following with reference to the accompanying drawings. In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on those shown in the drawings, and are used only for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present invention. In the description of the present invention, "a plurality" means two or more unless otherwise specified.

Referring to fig. 1, the simulated electric fireplace of the present embodiment includes a casing 10, and a simulated fuel 20 and a mars simulation device disposed in the casing 10; a window (not shown) communicated with the inner cavity of the shell 10 is arranged on the front side surface of the shell 10, and the spark simulation device is arranged in the inner cavity of the shell 10.

The simulated fuel 20 is disposed adjacent the window, and the simulated fuel 20 is visible when viewing the interior cavity of the housing from the window. A simulated fuel light source 21 for illuminating the simulated fuel is also arranged below the simulated fuel 20; preferably, the simulation fuel light source 21 is an LED light source, the LED light source is orange or orange, and the simulation fuel 21 is preferably simulation charcoal.

The spark simulation device is arranged behind the simulation fuel 21 and comprises a light source 31, a reflecting piece 32, a rotary reflecting component 33 and an imaging plate 34 which are arranged on the same light path; the light reflecting piece 32 is provided with a plurality of first light reflecting pieces 32a, the light emitted by the light source 31 irradiates on the first light reflecting pieces 32a to form a plurality of small light spots, and the small light spots are reflected to the rotary light reflecting component 33 and then reflected to the imaging plate 34 for imaging.

The light source 31 can generate concentrated light, and preferably, the light source 31 is a red or orange laser diode, and in this embodiment, the light source 31 is a laser diode. The light source 31 of the present invention may also be configured as a plurality of laser diodes, and be disposed toward the reflector 32 at a plurality of angles, so that the light emitted from the plurality of light sources 31 can be irradiated on the reflector 31.

The surface of the reflector 32 is a curved surface, and the first reflectors 32a are arranged on the curved surface 32; specifically, the light reflecting element 32 is a revolution body, and a bus of the revolution body is a single-peak curve segment; the rotation axis of the revolution body is perpendicular to the light beam emitted from the light source 31. The first light reflecting pieces are arranged into a circle along the circumferential direction of the revolution body and are closely arranged into a plurality of circles along the axis of the revolution body. Referring to fig. 2 and fig. 3, in the present embodiment, the middle of the light reflecting member 32 is large, and the two ends of the light reflecting member 32 are small, and preferably, the cross section of the light reflecting member 32 is a circle, and the diameter of the cross section of the light reflecting member gradually decreases from the middle to the two ends along the central axis. Further, the light reflecting member 32 is hollow or solid, and the light reflecting member 32 is fixedly disposed in the light path, so that the light emitted from the light source is irradiated on the light reflecting member 32. Further, the surface of the reflector 32 is provided with a plurality of first reflectors 32a, the first reflectors 32a are made of a reflective material, and the first reflectors 32a may be regular or irregular. Preferably, the first reflective sheets 32a are regular long strips, and are arranged in a circle along the circumferential direction of the curved body, and are closely arranged in a plurality of circles along the axial direction of the curved body, that is, a plurality of first reflective sheets are regularly and closely arranged on the surface of the curved body. Specifically, the first reflective sheets 32a are strip-shaped metal sheets, and each first reflective sheet 32a is soft and can be adhered to the outer surface of the reflective member 32a by means of adhesion. The light source 31 generates a first parallel light beam, and because the light beam has a certain size range (i.e. coverage area), when the size of the first reflector is smaller than the diameter of the light beam, the first parallel light beam can cover and irradiate a plurality of first reflectors, and each irradiated first reflector forms a plurality of second light beams with different reflection angles and reflects the second light beams onto the rotary reflector assembly.

Further, referring to fig. 2, the rotating reflective assembly 33 includes a rotating shaft 331, a motor 332, two clamping seats 333 and a plurality of second reflective sheets 334. The motor 332 is fixed on the side wall of the housing 10, and the rotating shaft 331 is connected to the rotating shaft of the motor 332 and extends axially along the rotating shaft of the motor 332; the two clamping seats 333 are disc-shaped, the middle parts of the two clamping seats are provided with through holes, and the edges along the circumferential direction are provided with a plurality of through holes at equal intervals; two ends of the rotating shaft 331 respectively pass through two through holes in the middle to be fixed between the two clamping seats 333, so that the two clamping seats 333 can rotate along with the rotating shaft 331. Each of the second reflective sheets 334 has a rectangular plate shape, and a plurality of square tooth-shaped reflective portions 334a are formed thereon. The first end of each second reflective sheet 334 has a certain width along the length direction, and a plurality of tooth-shaped reflective portions 334a are distributed along the length direction, and each tooth-shaped reflective portion 334a is regular long-strip-shaped and is arranged at equal intervals. The shape and size of the two ends of each second reflector 334 are matched with the through holes formed on the edges of the circumferences of the card holders 333, so that the two ends of each second reflector 334 can be respectively clamped in the two corresponding through holes of the two card holders 333, and are fixed between the two card holders 333 and parallel to the rotating shaft 331. The plurality of second reflectors 334 are arranged at intervals along the circumferential direction of the rotating shaft 331, two ends of each second reflector 334 are respectively clamped in the two clamping seats 333, and during installation, one end of each two adjacent second reflectors 334 is respectively inserted in the two clamping seats 333, so that the square tooth-shaped light reflecting portions 334a of the two adjacent second reflectors 334 are staggered with each other. Specifically, the second reflective sheets may be made of plastic, metal, or other reflective materials with reflective effect, and in this embodiment, the second reflective sheets are integrally formed. Furthermore, the tooth-shaped light reflecting parts are arranged in a staggered manner, namely, gaps between every two adjacent teeth of the tooth-shaped light reflecting part of one second light reflecting piece and the tooth-shaped light reflecting part of the other second light reflecting piece are opposite, so that when a light source vertically irradiates on each tooth-shaped light reflecting part and reflects, the light source can penetrate through the gaps between every two adjacent teeth of the adjacent second light reflecting pieces without being interfered by the adjacent second light reflecting pieces.

Further, the imaging plate 34 is a rear shell of the housing 10, and the rear shell is located behind the rotating reflector assembly 33. Preferably, the rear shell plate is pasted with brick-lined wallpaper.

The operation of the present invention will be described in detail below. Referring to fig. 3, the surface of the light-reflecting member is closely and regularly arranged with a plurality of first light-reflecting sheets, and when the light beam emitted from the light source irradiates the surface of the light-reflecting member, the light beam irradiates the plurality of first light-reflecting sheets at the same time because the light beam has a certain size. Here, assuming that the light emitted from the light source is simultaneously irradiated on the first reflectors B1, B2 and B3 located in the middle of the curved body, and the first reflectors B1, B2 and B3 are located on the same arc line in the axial direction of the curved body, in the horizontal direction, when the light emitted from the light source 31 is irradiated on the first reflector B1, the reflected light is B1; when the light emitted from the light source 31 irradiates the position B2, the reflected light is B2; when the light emitted from the light source 234 irradiates the position B3, the reflected light is B3; because the shape of the reflector 31 is large in the middle and small in the two ends, the first reflectors B1, B2 and B3 are on a curved surface, that is, the included angles between the 3 first reflectors and the axis are all different, according to the reflection principle of light, the reflected light rays B1, B2 and B3 can exhibit the effect of diffusing towards two sides, that is, the reflected light rays B1, B2 and B3 mutually diffuse outwards at a certain angle. Similarly, the vertical direction also generates the outward diffused reflection light. Therefore, when the light source emits the first parallel light beams to irradiate on the first reflectors with different angles, according to the reflection principle of light, the horizontal direction and the vertical direction generate outward diffused reflected light beams, namely, second parallel light beams with different angles are generated, and each first reflector correspondingly generates one or more second parallel light beams, so that a plurality of small light spots which are outward diffused and have irregular reflection angles are visually formed. The second parallel light beams generated by the light reflecting piece are reflected to the second light reflecting piece rotating along with the motor, and due to the arrangement rule of the tooth-shaped light reflecting parts on the second light reflecting piece, the second light reflecting piece reflects the second parallel light beams again to form third parallel light beams to the imaging plate, the shape of small light spots of the third parallel light beams is kept, and the effect that the small light spots float upwards is shown in the visual effect.

During the use, in this embodiment 1, the light source produces a bundle of light beam, the light beam shines on the reflector of fixed setting, owing to be equipped with a plurality of first reflectors in the irradiation range of light beam, every first reflector visual effect corresponds produces a little light spot, little light spot reflection to rotatory reflection of light subassembly on, owing to the second reflector of rotatory reflection of light subassembly rule of arranging, when second reflector rotates along with rotation axis and motor, it projects formation of image on the back shell board to drive little light spot, illuminate the back shell board promptly and leave the facula of mars shape, the drift velocity on the back shell board of controllable mars of rotational speed through control motor, in order to obtain best visual effect, and can produce the effect of mars drunkenness on the back shell board.

Example 2

Referring to fig. 4, embodiment 2 of the present invention is substantially the same as embodiment 1, except that: the imaging plate is arranged at different positions and structures. In this embodiment 2, the imaging plate is a light-transmitting plate 34a, and the light-transmitting plate 34a is disposed between the artificial fuel 20 and the rotating reflective member 32. Preferably, the light-transmitting plate 34a is a translucent plate formed by processing a hard transparent plastic with excellent optical performance.

During the use, in this embodiment 2, the punctiform light source is located between rotatory reflector assembly and the light-passing board, the light beam shines on the reflector of fixed setting, because be equipped with a plurality of first reflectors in the irradiation range of light beam, every first reflector visual effect corresponds produces a little light spot, little light spot reflects to rotatory reflector assembly on, because the second reflector of rotatory reflector assembly arranges the rule, when the second reflector rotates along with rotation axis and motor, it projects on the light-passing board at middle part to drive little light spot, leave mars shape's facula on the translucent board promptly, can control the drift speed of mars on the light-passing board through the rotational speed of control motor, in order to obtain best visual effect, and can produce the effect of mars drunkenness on the translucent board.

The invention has the following beneficial effects: 1. the invention utilizes concentrated light beams emitted by the point light source to irradiate the light reflecting piece provided with the first light reflecting pieces to form a plurality of small light spots, the light reflecting piece reflects the small light spots to the rotary light reflecting component, and then reflects the small light spots to the imaging plate or the light transmitting plate to be in a spark shape, meanwhile, the rotary light reflecting component continuously rotates, and the shape and the position of the light spots irradiated on the imaging plate can be changed along with the change of the rotating angle, so that the dim light spots are formed on the imaging plate, and the effect of simulating the spark jump of the up-down movement is achieved. 2. Because the reflector is a cylinder with a large middle and small two ends, the angles of each first reflector arranged on the surface of the reflector are different, outward-diffused reflection light can be generated in the horizontal or vertical direction, the reflection range in the horizontal or vertical direction is enlarged, and therefore the coverage area of the small light spot reflected to the rotary reflecting component is large. 3. The second light reflecting pieces in the rotary light reflecting assembly are regularly arranged, and the small light spots formed by the light reflecting pieces are secondarily reflected to the imaging plate for imaging through the second light reflecting pieces which are regularly arranged, so that the shape of the small light spots can still be kept.

The present invention is not limited to the above-described embodiments, and various modifications and variations of the present invention are intended to be included within the scope of the claims and the equivalent technology of the present invention if they do not depart from the spirit and scope of the present invention.

Claims (10)

1. A mars simulation apparatus, comprising:

the light source emits a first parallel light beam after being electrified;

the light reflecting piece is fixedly arranged in the first parallel light beam path, and is provided with a plurality of first light reflecting sheets which reflect the first parallel light beams into a plurality of second parallel light beams with different reflection angles;

the rotary light reflecting assembly comprises a rotating shaft and a plurality of second light reflecting sheets arranged on the rotating shaft, and the second light reflecting sheets sequentially and circularly interfere into the path of the second parallel light beams along with the rotation of the rotating shaft and reflect a plurality of third parallel light beams; and

an imaging plate fixedly disposed in the third plurality of parallel beam paths.

2. A mars simulation apparatus according to claim 1, wherein: the surface of the light reflecting piece irradiated by the first parallel light beams is a curved surface, and the plurality of first light reflecting pieces are arranged on the curved surface.

3. A mars simulation apparatus according to claim 2, wherein: the light reflecting piece is a revolution body, and a bus of the revolution body is a unimodal curve section; the rotation axis of the revolution body is perpendicular to the first parallel light beam.

4. A mars simulation apparatus according to claim 3, wherein: the first light reflecting pieces are arranged into a circle along the circumferential direction of the revolution body and are closely arranged into a plurality of circles along the axis of the revolution body.

5. A Mars simulation apparatus according to claim 4, wherein: the light source is at least one laser diode.

6. A Mars simulation apparatus according to claim 5, wherein: the rotary reflecting component also comprises a motor and two clamping seats; the motor is fixedly arranged; one end of the rotating shaft is coaxially connected with an output shaft of the motor; the two clamping seats are alternately arranged on the shaft body of the rotating shaft in a penetrating way; the plurality of second light reflecting pieces are arranged at intervals along the circumferential direction of the rotating shaft, and two ends of each second light reflecting piece are respectively clamped in the two clamping seats.

7. A Mars simulation apparatus according to claim 6, wherein: each second reflecting sheet is in a rectangular flat plate shape, and a plurality of square tooth-shaped reflecting parts are formed on the second reflecting sheet.

8. A mars simulation apparatus according to claim 7, wherein: the square tooth-shaped light reflecting parts on two adjacent second light reflecting sheets which are arranged at intervals along the axial direction are staggered with each other.

9. A mars simulation apparatus according to any one of claims 1 to 8, wherein: the simulation fuel is arranged in front of the imaging plate.

10. The utility model provides a emulation electric fireplace, includes a casing, the leading flank of casing is equipped with the window with casing inner chamber intercommunication, the casing inner chamber is equipped with spark simulation device, its characterized in that: the flame simulating assembly according to any one of claims 1 to 9.

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