CN217899601U

CN217899601U - Atmosphere lamp and lighting system

Info

Publication number: CN217899601U
Application number: CN202221927009.3U
Authority: CN
Inventors: 胡然
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-07-25
Filing date: 2022-07-25
Publication date: 2022-11-25
Anticipated expiration: 2032-07-25

Abstract

The application provides an atmosphere lamp and lighting system. The atmosphere lamp comprises a lamp shell assembly, a rotating assembly, a light source assembly and a Fresnel lens, wherein the lamp shell assembly is provided with a mounting cavity and a light-emitting window which are communicated, the rotating assembly is positioned in the mounting cavity and is rotationally connected with the lamp shell assembly, the light source assembly is connected with the rotating assembly, the light source assembly is arranged by deviating from the rotating center of the rotating assembly, the Fresnel lens is mounted in the mounting cavity, the Fresnel lens is positioned on the light-emitting side of the light source assembly and is arranged at intervals with the light source assembly, and the light-emitting window is positioned on the light-emitting side of the Fresnel lens; the light-emitting window is circular or oval, and the light source assembly is further arranged deviating from the axis of the light-emitting window. Because the rotating assembly is located the installation intracavity and rotates with the lamp housing subassembly and be connected, and the light source subassembly is connected in rotating assembly for the light source subassembly is rotatable, because the skew center of rotation setting of light source subassembly rotating assembly makes the light of meteorite appearance can change dynamically again.

Description

Atmosphere lamp and lighting system

Technical Field

The utility model relates to a lighting system's technical field especially relates to an atmosphere lamp and lighting system.

Background

The atmosphere lamp is also called an LED atmosphere lamp, is a perfect choice for theme parks, hotels, homes, exhibitions, businesses and artistic lighting, and creates a required atmosphere for life of people. The atmosphere lamp is aimed at simulating the shape of falling of meteorites, namely the meteorite lamp, however, the shape of the facula of the atmosphere lamp is single and cannot move, so that the atmosphere effect of the atmosphere lamp is poor.

SUMMERY OF THE UTILITY MODEL

The utility model aims at overcoming the weak point among the prior art, provide an atmosphere lamp and lighting system that the shape is abundant and can change dynamically.

The purpose of the utility model is realized through the following technical scheme:

an ambience lamp, comprising:

the lamp shell assembly is provided with a mounting cavity and a light outlet window which are communicated;

the rotating assembly is positioned in the mounting cavity and is rotationally connected with the lamp shell assembly;

the light source assembly is connected to the rotating assembly and is arranged in a manner of deviating from the rotating center of the rotating assembly; and

the Fresnel lens is arranged in the mounting cavity, the Fresnel lens is positioned on the light-emitting side of the light source component and is arranged at intervals with the light source component, and the light-emitting window is positioned on the light-emitting side of the Fresnel lens; the light-emitting window is circular or oval, and the light source assembly is further deviated from the axis of the light-emitting window.

In one embodiment, the atmosphere lamp further comprises a colored glass piece, the colored glass piece is installed in the installation cavity, the colored glass piece is located on the light emitting side of the Fresnel lens, and the light emitting window is located on the light emitting side of the Fresnel lens.

In one embodiment, the atmosphere lamp further comprises a mounting piece, the mounting piece is located in the mounting cavity and is detachably connected with the lamp shell assembly, the mounting piece is provided with a light-transmitting hole, and the colored glass piece is connected to the mounting piece and is arranged corresponding to the light-transmitting hole.

In one embodiment, the inner wall of the mounting cavity is convexly provided with a limiting part, and the limiting part is provided with a spacing hole;

the installed part includes collar, connecting portion and butt portion, the collar is located spacing portion is neighbouring one side of light-emitting window, connecting portion connect in the collar, connecting portion still wear to locate keep away a hole, butt portion connect in connecting portion, butt portion is used for passing keep away a hole, butt portion is in when the installed part rotates predetermined angle with collar butt respectively is in spacing relative both sides.

In one embodiment, an included angle exists between the abutting part and the connecting part.

In one embodiment, the colored glass member is clamped to the mounting member.

In one embodiment, the atmosphere lamp further comprises a driving assembly, the driving assembly is mounted on the lamp shell assembly, and a power output end of the driving assembly is connected with the rotating assembly; and/or the like, and/or,

the rotating assembly is a radiator.

In one embodiment, the rotating assembly comprises a rotating body and a driven gear, the rotating body is located in the installation cavity and is rotatably connected with the lamp housing assembly, the driven gear is connected with the rotating body, and the driven gear is arranged along the circumferential direction of the rotating body;

the driving assembly comprises a driving piece and a driving gear, the driving piece is installed on the lamp housing assembly, the driving gear is connected to the power output end of the driving piece, and the driving gear is meshed with the driven gear.

In one embodiment, a limiting part is convexly arranged on the inner wall of the mounting cavity, a connecting groove is formed in the limiting part, and the Fresnel lens is located in the connecting groove and connected with the limiting part.

A lighting system comprising an atmosphere lamp as described in any of the above embodiments.

Compared with the prior art, the utility model discloses at least, following advantage has:

1. because the light-emitting window is circular or oval, the axis interval that the light source subassembly still deviates from the light-emitting window sets up, make the facula that the light source subassembly jetted out through the light-emitting window be the appearance that meteorite falls, again because runner assembly is located the installation intracavity and rotates with the lamp house subassembly to be connected, and the light source subassembly is connected in the runner assembly, make the light source subassembly rotatable, again because the skew runner assembly's of light source subassembly center of rotation sets up, make the meteorite appearance facula of the rotation that the light-emitting window can jet out, even can the dynamic change of the light of the meteorite appearance.

2. When the rotating speed of the light source component reaches a certain value, a plurality of circularly arranged meteorite-shaped light spots are formed, and the shapes of the light spots are enriched.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required for the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention, and therefore should not be considered as limiting the scope, and that those skilled in the art can also obtain other related drawings based on these drawings without inventive efforts.

FIG. 1 is a schematic view of an embodiment of an atmosphere lamp;

FIG. 2 isbase:Sub>A cross-sectional view along line A-A of the atmosphere lamp shown in FIG. 1;

FIG. 3 is an enlarged schematic view at B of the ambience lamp shown in FIG. 2;

FIG. 4 is a spot diagram of the atmosphere lamp shown in FIG. 1;

FIG. 5 is a schematic view of a partial structure of the ambience lamp shown in FIG. 1;

FIG. 6 is a schematic structural view of the mounting member of the atmosphere lamp shown in FIG. 1.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described more fully hereinafter with reference to the accompanying drawings. The preferred embodiments of the present invention are shown in the drawings. The invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

The application provides an atmosphere lamp, which comprises a lamp housing component, a rotating component, a light source component and a Fresnel lens, wherein the lamp housing component is provided with a communicated installation cavity and a light emitting window; the light-emitting window is circular or oval, and the light source assembly is further deviated from the axis of the light-emitting window. The application also provides a light system, which comprises the atmosphere lamp.

Foretell atmosphere lamp and lighting system, because the light-emitting window is circular or oval, the axis interval that the light source subassembly still deviates the light-emitting window sets up, make the light spot that the light source subassembly jetted out through the light-emitting window be the appearance that meteorite falls, again because the runner assembly is located the installation cavity and rotates with the lamp house subassembly to be connected, and the light source subassembly is connected in the runner assembly, make the light source subassembly rotatable, again because the skew centre of rotation of light source subassembly sets up, make the meteorite appearance facula of the rotation that the light-emitting window can jet out, even can the dynamic change of the light of the meteorite appearance. And when the rotating speed of the light source component reaches a certain value, a plurality of light spots of meteorite shapes arranged in a surrounding mode are formed, and the shapes of the light spots are enriched.

In order to better understand the technical scheme and the beneficial effects of the present application, the following detailed description is further provided in conjunction with specific embodiments:

as shown in fig. 1 to 3, an atmosphere lamp 10 according to an embodiment includes a lamp housing assembly 100, a rotating assembly 200, a light source assembly 300, and a fresnel lens 400, wherein the lamp housing assembly 100 forms a mounting cavity 101 and an exit window 102, and the mounting cavity 101 and the exit window 102 are in communication. The rotating assembly 200 is disposed in the mounting cavity 101 and rotatably connected to the lamp housing assembly 100, the light source assembly 300 is connected to the rotating assembly 200, and the light source assembly 300 is offset from the rotation center of the rotating assembly 200, so that the light source assembly 300 eccentrically rotates, that is, the light source assembly 300 rotates around the rotation center of the rotating assembly 200. The fresnel lens 400 is installed in the installation cavity 101, and the fresnel lens 400 is located the light-emitting side of light source subassembly 300 and sets up with the interval of light source subassembly 300 to restrain the light divergence of the play of light source subassembly 300, light-emitting window 102 is located the light-emitting side of fresnel lens 400, so that the light of light source subassembly 300 loops through fresnel lens 400 and light-emitting window 102 and jets out. The light-emitting window 102 is circular or elliptical, and the light source assembly 300 is further disposed deviating from an axis of the light-emitting window 102.

As shown in fig. 3 and 4, in the present embodiment, the light-exiting window 102 is circular or elliptical, and the light source assembly 300 is further disposed at an interval deviating from the axis of the light-exiting window 102, so that the light spot emitted by the light source assembly 300 through the light-exiting window 102 has the shape of falling meteorite as shown in fig. 4. For example, the height of the light source assembly 300 is higher than the height of the center of the light-emitting window 102, so that the light on the upper side of the light source assembly 300 is shielded by the lamp housing assembly 100, and then the upper end of the light spot emitted by the light-emitting window 102 through the light-emitting assembly 300 is thinner, and meanwhile, the light on the lower side of the light source assembly 300 is not shielded or less shielded, so that the lower end of the light spot emitted by the light-emitting assembly 300 through the light-emitting window 102 is thicker, and because the light-emitting window 102 is circular or arc-shaped, the light spot is transited to the thicker lower end by the thinner upper end assembly, and then the falling appearance of meteorite is formed. For another example, the height of the light source assembly 300 is lower than the height of the center of the light-emitting window 102, so that the light on the lower side of the light source assembly 300 is shielded by the lamp housing assembly 100, and then the lower end of the light spot emitted by the light-emitting window 102 of the light source assembly 300 is thinner, and meanwhile, the light on the upper side of the light source assembly 300 is not shielded or less shielded, so that the upper end of the light spot emitted by the light source assembly 300 through the light-emitting window 102 is thicker, and since the light-emitting window 102 is circular or arc-shaped, the light spot is transited to the thicker upper end by the thinner lower end assembly, and then the falling appearance of the inverted meteorite is formed.

Above-mentioned atmosphere lamp 10, because light-emitting window 102 is circular or oval, the axis interval that light source subassembly 300 still squints light-emitting window 102 sets up, make light source subassembly 300 be the appearance that meteorite falls through the facula that light-emitting window 102 jetted out, again because runner assembly 200 is located installation cavity 101 and rotates with lamp housing subassembly 100 and be connected, and light source subassembly 300 connects in runner assembly 200, make light source subassembly 300 rotatable, again because the skew centre of rotation setting of runner assembly 200 of light source subassembly 300, make the rotatory meteorite appearance facula that light-emitting window 102 can jet out, even can the dynamic change of the light of the meteorite appearance. Moreover, when the rotating speed of the light source component 300 reaches a certain value, a plurality of meteorite-shaped faculas arranged in a surrounding mode are formed, and the shapes of the faculas are enriched.

As shown in fig. 3, in one embodiment, the atmosphere lamp 10 further includes a driving assembly 700, the driving assembly 700 is mounted to the lamp housing assembly 100, and a power output end of the driving assembly 700 is connected to the rotating assembly 200, so that the driving assembly 700 is used for driving the rotating assembly 200 to rotate, and further, the light source assembly 300 is rotated. In this embodiment, since the driving assembly 700 drives the light source assembly 300 to rotate, the rotation automation degree of the light source assembly 300 is higher, and thus the atmosphere lamp 10 is more convenient to use.

As shown in fig. 3, in one embodiment, the rotating assembly 200 is a heat sink, which reduces the heat accumulation of the light source assembly 300, and further increases the service life of the light source assembly 300.

As shown in fig. 3, in one embodiment, the rotating assembly 200 includes a rotating body 210 and a driven gear 220, the rotating body 210 is located in the mounting cavity 101 and is rotatably connected to the lamp housing assembly 100, the driven gear 220 is connected to the rotating body 210, and the driven gear 220 is disposed along a circumferential direction of the rotating body 210. The driving assembly 700 includes a driving member 710 and a driving gear 720, the driving member 710 is mounted on the lamp housing assembly 100, the driving gear 720 is connected to a power output end of the driving member 710, and the driving gear 720 is engaged with the driven gear 220. In this embodiment, the driven gear 220 is connected to the outside of the rotating body 210, the driving member 710 is a motor, the driving member 710 drives the driving gear 720 to rotate, the driving gear 720 drives the driven gear 220 to rotate through the meshing transmission, the driven gear 220 drives the rotating body 210 to rotate, and the rotating body 210 drives the light source assembly 300 to rotate, so as to form a rotating meteorite falling light spot.

As shown in fig. 3, in one embodiment, a limiting portion 110 is convexly disposed on an inner wall of the mounting cavity 101, the limiting portion 110 is formed with a connecting groove 112, and the fresnel lens 400 is located in the connecting groove 112 and connected to the limiting portion 110, so that the fresnel lens 400 is mounted in the mounting cavity 101. In this embodiment, the fresnel lens 400 is located in the connecting slot 112 and abuts against the slot wall of the connecting slot 112, so that the fresnel lens 400 is installed in the connecting slot 112, and the fresnel lens 400 is installed in the installation cavity 101.

As shown in fig. 3, in one embodiment, the atmosphere lamp 10 further includes a colored glass piece 500, the colored glass piece 500 is installed in the installation cavity 101, the colored glass piece 500 is located on the light-emitting side of the fresnel lens 400, and the light-emitting window 102 is located on the light-emitting side of the fresnel lens 400. In this embodiment, the colored glass member 500 is a sheet structure, so that the light spots have colors and/or various shapes, and the richness of the light spots is improved. It is understood that the colored glass has at least one color and the colored glass may also have a pattern.

As shown in fig. 3, in one embodiment, the atmosphere lamp 10 further includes a mounting member 600, the mounting member 600 is disposed in the mounting cavity 101 and detachably connected to the lamp housing assembly 100, the mounting member 600 is formed with a light-transmitting hole 601, and the colored glass member 500 is connected to the mounting member 600 and disposed corresponding to the light-transmitting hole 601. In this embodiment, because the installation piece 600 can be dismantled and connect in lamp housing assembly 100 for colored glass piece 500 can be dismantled and connect in lamp housing assembly 100 through installation piece 600, so make atmosphere lamp 10 removable different colored glass piece 500, improved the facula abundance of atmosphere lamp 10.

As shown in fig. 5 and 6, in one embodiment, a limiting portion 110 is protruded from an inner wall of the mounting cavity 101, and the limiting portion 110 is formed with a clearance hole 111. The mounting member 600 includes a mounting ring 610, a connecting portion 620 and a abutting portion 630, the mounting ring 610 is located on one side of the limiting portion 110 adjacent to the light-emitting window 102, the connecting portion 620 is connected to the mounting ring 610, the connecting portion 620 further penetrates through the avoiding hole 111, the abutting portion 630 is connected to the connecting portion 620, the abutting portion 630 is used for penetrating through the avoiding hole 111, and the abutting portion 630 abuts against two opposite sides of the limiting portion 110 respectively with the mounting ring 610 when the mounting member 600 rotates to a predetermined angle.

As shown in fig. 5 and fig. 6, in the present embodiment, when the mounting member 600 is mounted on the lamp housing assembly 100, the abutting portion 630 of the mounting member 600 is aligned with the avoiding hole 111, then the abutting portion 630 passes through the avoiding hole 111 and enters one side of the limiting portion 110 away from the light-emitting window 102, and the mounting ring 610 abuts against one side of the limiting portion 110 adjacent to the light-emitting window 102, and then the mounting ring 610 is rotated to abut the connecting portion 620 against the groove wall of the avoiding hole 111, and abut the abutting portion 630 against one side of the limiting portion 110 away from the light-emitting window 102, so that the abutting portion 630 and the mounting ring 610 abut against two opposite sides of the limiting portion 110, respectively, and the mounting member 600 is mounted on the lamp housing assembly 100. When the mounting member 600 is detached from the lamp housing assembly 100, the mounting ring 610 is rotated to align the abutting portion 630 with the avoiding hole 111, and to misalign the abutting portion 630 and the limiting portion 110 away from one side of the light-emitting window 102, and then the mounting member 600 can be taken out.

As shown in fig. 6, in one embodiment, an included angle exists between the abutting portion 630 and the connecting portion 620, so that the abutting portion 630 abuts against a side surface of the limiting portion 110 away from the light-emitting window 102 when the mounting member 600 rotates to a predetermined angle.

As shown in fig. 6, in one embodiment, the colored glass piece 500 is clamped to the mounting member 600, so that the colored glass piece 500 can be easily and conveniently mounted on and dismounted from the mounting member 600. Further, installed part 600 includes collar 610, collar 610 includes ring 611 and joint body 612, and ring 611 is located installation cavity 101 and can dismantle with lamp housing assembly 100 and be connected, and breach 6111 has been seted up to ring 611, and joint body 612 is located breach 6111 and is connected with ring 611, and colored glass 500 joint is between ring 611 and joint body 612 to improve the convenience of colored glass 500 dismouting in installed part 600.

The present application further provides a lighting system comprising an ambience lamp 10 as described in any of the above embodiments. As shown in fig. 1 to 3, in one embodiment, the atmosphere lamp 10 includes a lamp housing assembly 100, a rotating assembly 200, a light source assembly 300, and a fresnel lens 400, wherein the lamp housing assembly 100 forms a mounting cavity 101 and an exit window 102, and the mounting cavity 101 and the exit window 102 are in communication. The rotating assembly 200 is disposed in the mounting cavity 101 and rotatably connected to the lamp housing assembly 100, the light source assembly 300 is connected to the rotating assembly 200, and the light source assembly 300 is offset from the rotation center of the rotating assembly 200, so that the light source assembly 300 eccentrically rotates, that is, the light source assembly 300 rotates around the rotation center of the rotating assembly 200. The fresnel lens 400 is installed in the installation cavity 101, the fresnel lens 400 is located at the light-emitting side of the light source assembly 300 and is spaced from the light source assembly 300 to inhibit the emitted lamp tube of the light source assembly 300 from diverging, and the light-emitting window 102 is located at the light-emitting side of the fresnel lens 400 to enable the light of the light source assembly 300 to sequentially pass through the fresnel lens 400 and the light-emitting window 102 to be emitted. The light-emitting window 102 is circular or elliptical, and the light source assembly 300 is further disposed deviating from an axis of the light-emitting window 102.

As shown in fig. 3 and 4, in the present embodiment, the light-exiting window 102 is circular or elliptical, and the light source assembly 300 is further disposed at an interval deviating from the axis of the light-exiting window 102, so that the light spot emitted by the light source assembly 300 through the light-exiting window 102 has the shape of falling meteorite. For example, the height of the light source assembly 300 is higher than the height of the center of the light-emitting window 102, so that the light on the upper side of the light source assembly 300 is shielded by the lamp housing assembly 100, and further the upper end of the light spot emitted by the light-emitting window 102 of the light source assembly 300 is thinner, and meanwhile, the light on the lower side of the light source assembly 300 is not shielded or less shielded, so that the lower end of the light spot emitted by the light source assembly 300 through the light-emitting window 102 is thicker, and further, because the light-emitting window 102 is circular or arc-shaped, the light spot is transited to the thicker lower end by the thinner upper end assembly, and further, the falling appearance of meteorite is formed. For another example, the height of the light source assembly 300 is lower than the height of the center of the circle of the light-emitting window 102, so that the light on the lower side of the light source assembly 300 is shielded by the lamp housing assembly 100, and then the lower end of the light spot emitted by the light-emitting window 102 through the light-emitting assembly 300 is thinner, and meanwhile, the light on the upper side of the light source assembly 300 is not shielded or shielded less, so that the upper end of the light spot emitted by the light-emitting assembly 300 through the light-emitting window 102 is thicker, and since the light-emitting window 102 is circular or arc-shaped, the light spot is transited from the thinner lower end assembly to the thicker upper end, and then the falling shape of the inverted meteorite is formed.

Above-mentioned lighting system, because light-emitting window 102 is circular or oval, light source subassembly 300 still deviates from the axis interval setting of light-emitting window 102, make the facula that light source subassembly 300 jetted out through light-emitting window 102 be the appearance that meteorite falls, because runner assembly 200 is located installation cavity 101 and rotates with lamp housing subassembly 100 again and be connected, and light source subassembly 300 connects in runner assembly 200, make light source subassembly 300 rotatable, because the skew centre of rotation setting of light source subassembly 300 rotates subassembly 200 again, make the rotatory meteorite appearance facula that light-emitting window 102 can jet, even can the dynamic change of the light of the meteorite appearance. Moreover, when the rotating speed of the light source assembly 300 reaches a certain value, a plurality of light spots with meteorite shapes arranged in a surrounding mode are formed, and the shapes of the light spots are enriched.

1. because the light-emitting window 102 is circular or oval, the axis interval that light source subassembly 300 still deviates from light-emitting window 102 sets up, make the facula that light source subassembly 300 jetted out through light-emitting window 102 be the appearance that meteorite falls, because runner assembly 200 is located installation cavity 101 and rotates with lamp house subassembly 100 again and be connected, and light source subassembly 300 connects in runner assembly 200, make light source subassembly 300 rotatable, because the skew center of rotation setting of runner assembly 200 of light source subassembly 300 again, make the rotatory meteorite appearance facula that light-emitting window 102 can jet, even the light of the meteorite appearance can dynamic change.

2. When the rotating speed of the light source assembly 300 reaches a certain value, a plurality of circularly arranged meteorite-shaped light spots are formed, and the shapes of the light spots are enriched.

The above-mentioned embodiments only represent several embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the invention. It should be noted that, for those skilled in the art, without departing from the concept of the present invention, several variations and modifications can be made, which all fall within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims

1. An ambience lamp, characterized by comprising:

2. The ambience lamp of claim 1, further comprising a colored glass piece mounted in the mounting cavity, the colored glass piece being located on a light exit side of the Fresnel lens, the light exit window being located on the light exit side of the Fresnel lens.

3. The ambience lamp of claim 2, further including a mounting member positioned within the mounting chamber and removably coupled to the lamp housing assembly, the mounting member defining a light-transmitting aperture, the colored glass member being coupled to the mounting member and positioned in correspondence with the light-transmitting aperture.

4. The atmosphere lamp according to claim 3, wherein a limiting part is convexly arranged on the inner wall of the mounting cavity, and a clearance hole is formed in the limiting part;

the mounting part comprises a mounting ring, a connecting part and a butting part, the mounting ring is located at one side, close to the light outlet window, of the limiting part, the connecting part is connected to the mounting ring, the connecting part is further arranged in the avoiding hole in a penetrating mode, the butting part is connected to the connecting part and is used for penetrating through the avoiding hole, and the butting part is in abutting connection with the mounting ring at two opposite sides of the limiting part when the mounting part rotates to a preset angle.

5. The atmosphere lamp according to claim 4, wherein an included angle exists between the abutting portion and the connecting portion.

6. The atmosphere lamp of claim 3, wherein the colored glass piece is snapped to the mounting piece.

7. The atmosphere lamp of claim 1, further comprising a drive assembly mounted to the lamp housing assembly, a power output of the drive assembly being coupled to the rotating assembly; and/or the presence of a catalyst in the reaction mixture,

the rotating assembly is a radiator.

8. The atmosphere lamp of claim 7, wherein the rotating assembly comprises a rotating body and a driven gear, the rotating body is located in the mounting cavity and is rotatably connected with the lamp housing assembly, the driven gear is connected to the rotating body, and the driven gear is arranged along the circumferential direction of the rotating body;

9. The atmosphere lamp as claimed in claim 1, wherein a limiting portion is convexly disposed on an inner wall of the mounting cavity, a connecting groove is formed on the limiting portion, and the Fresnel lens is located in the connecting groove and connected with the limiting portion.

10. A light system, characterized in that it comprises an ambience lamp as claimed in any one of claims 1 to 9.