CN214249470U - Lens and lamp - Google Patents

Abstract

The application discloses lens and lamps and lanterns relates to the domestic appliance field. A lens comprises a first light transmission part, wherein a first cavity is formed on the first light transmission part, the inner side surface of the first cavity is used as a first light incoming surface, the surface of the first light transmission part deviating from the first cavity is used as a first light outgoing surface, and the first light transmission part is provided with a first optical axis; the second light transmission part is arranged on the first light transmission part, a second cavity is formed on the second light transmission part, the inner side surface of the second cavity is used as a second light inlet surface, the surface of the second light transmission part, which deviates from the second cavity, is used as a second light outlet surface, and the second light transmission part is provided with a second optical axis; the first optical axis and the second optical axis are arranged at an included angle. A lamp comprises a lamp source and a lens, wherein the lamp source comprises a first lamp source and a second lamp source, the first lamp source is opposite to a first light incoming surface, and the second lamp source is opposite to a second light incoming surface. The application can solve the problem that the conventional pinup lamp illumination zone is limited.

Description

Lens and lamp

Technical Field

The application belongs to the technical field of household appliances, and particularly relates to a lens and a lamp.

Background

The wall washing lamp can be used for architectural decoration and illumination and can also be used for outlining large buildings. However, the conventional wall washer is limited in installation position to the top or bottom of the wall, and the lens is a substantially TIR (Total Internal reflection) lens, however, the conventional lens can only illuminate a single wall surface, so that the wall washer can only illuminate the top or bottom of the wall, thereby limiting the illumination range of the wall washer.

Disclosure of Invention

The embodiment of the application aims to provide a lens and a lamp, and the problem that the illumination range of a conventional wall washer is limited can be solved.

In order to solve the technical problem, the present application is implemented as follows:

an embodiment of the present application provides a lens, including:

the light source comprises a first light transmission part, a second light transmission part and a light source, wherein a first cavity is formed on the first light transmission part, the inner side surface of the first cavity is used as a first light incoming surface, the surface of the first light transmission part, which deviates from the first cavity, is used as a first light outgoing surface, and the first light transmission part is provided with a first optical axis;

the second light transmission part is arranged on the first light transmission part, a second cavity is formed on the second light transmission part, the inner side surface of the second cavity is used as a second light incoming surface, the surface of the second light transmission part, which deviates from the second cavity, is used as a second light outgoing surface, and the second light transmission part is provided with a second optical axis;

the first optical axis and the second optical axis are arranged at an included angle.

An embodiment of the present application further provides a lamp, including:

a lens;

the light source comprises a first light source and a second light source, at least part of the first light source is arranged opposite to the first light incident surface, and at least part of the second light source is arranged opposite to the second light incident surface;

the light emitted by the first light source irradiates the first light incoming surface, is projected by the first light transmission part and then is emitted by the first light emitting surface, and the light emitted by the second light source irradiates the second light incoming surface, is projected by the second light transmission part and then is emitted by the second light emitting surface.

In this application embodiment, light can propagate through the first light path that first income plain noodles, first printing opacity portion and first play plain noodles formed, and light can also propagate through the second light path that second income plain noodles, second printing opacity portion and second go out the plain noodles and form, compare in conventional lens, the irradiation range of light can be enlarged through the lens of first printing opacity portion and second printing opacity portion constitution in this application embodiment, thereby make the irradiation range of the lamps and lanterns of using this lens no longer restricted, promoted the illuminating effect of lamps and lanterns greatly.

Drawings

FIG. 1 is a schematic structural diagram of a lens disclosed in an embodiment of the present application;

FIG. 2 is a front view of a lens disclosed in an embodiment of the present application;

FIG. 3 is a cross-sectional view of a first form of a lens as disclosed in an embodiment of the present application;

FIG. 4 is a cross-sectional view of a second form of lens as disclosed in an embodiment of the present application;

FIG. 5 is a cross-sectional view of a luminaire disclosed in an embodiment of the present application;

fig. 6 is a schematic view of a lamp being hung between a ceiling surface and a side wall surface according to the embodiment of the present application.

Description of reference numerals:

100-a light source; 110-a first light source; 120-a second light source;

200-a lens; 210-a first light-transmitting portion; 211-a first light incident surface; 212-a first light-emitting surface; 213-a first basal plane; 214-a first cavity; 220-a second light-transmitting portion; 221-a second light incident surface; 222-a second light emitting surface; 223-a second base surface; 224-a second cavity; 230-a connecting portion; 231 — a first groove; 232-a second groove;

310-a first fixing plate; 320-a second fixing plate;

400-ceiling face;

500-side wall surface;

m-a first optical axis; n-second optical axis.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are some, but not all, embodiments of the present application. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

The terms first, second and the like in the description and in the claims of the present application are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It will be appreciated that the data so used may be interchanged under appropriate circumstances such that embodiments of the application may be practiced in sequences other than those illustrated or described herein, and that the terms "first," "second," and the like are generally used herein in a generic sense and do not limit the number of terms, e.g., the first term can be one or more than one. In addition, "and/or" in the specification and claims means at least one of connected objects, a character "/" generally means that a preceding and succeeding related objects are in an "or" relationship.

The embodiments of the present application are described in detail below with reference to the accompanying drawings through specific embodiments and application scenarios thereof.

Referring to fig. 1 to 4, an embodiment of the present application discloses a lens 200, and the disclosed lens 200 includes a first light-transmitting portion 210 and a second light-transmitting portion 220. Alternatively, the lens 200 may have a bar-shaped structure, and when the lens 200 is applied to the wall washer, the bar-shaped lens 200 may extend in a direction parallel to a connection line between the ceiling surface 400 and the side wall surface 500, so that an illuminated area may be formed at the connection area between the ceiling surface 400 and the side wall surface 500 to enhance the aesthetic sense of the building. Of course, the specific structure of the lens 200 and the specific application environment of the lens 200 are not limited in the embodiments of the present application.

The second transparent portion 220 is disposed on the first transparent portion 210. Alternatively, one side of the first light-transmitting portion 210 may be connected to one side of the second light-transmitting portion 220 to jointly splice the lens 200 into a whole. Of course, the first light-transmitting portion 210 and the second light-transmitting portion 220 may be integrally molded to directly form the lens 200 as a whole. The formation manner of the lens 200 is not limited in the embodiment of the present application.

The first light-transmitting portion 210 has a first optical axis M, the second light-transmitting portion 220 has a second optical axis N, and the first optical axis M and the second optical axis N form an included angle. Alternatively, the extending direction of the first optical axis M and the extending direction of the second optical axis N may be perpendicular to each other. In addition, the extending direction of the first optical axis M and the extending direction of the second optical axis N may form other angles, such as an acute angle, an obtuse angle, etc., and the specific angle may be selected according to the application environment of the lens 200, and the specific degree of the included angle is not limited in the embodiment of the present application. Here, the optical axis of the lens 200 refers to a line perpendicular to the mounting surface of the lamp 100 and passing through the center of the lamp 100.

Referring to fig. 3 and 4, a first cavity 214 is formed on the first light-transmitting portion 210. Optionally, the first cavity 214 is opened on the plane of the first light-transmitting portion 210 along the length direction of the lens 200, and the first cavity 214 has an opening on the plane of the first light-transmitting portion 210, and the opening is used for disposing the lamp source 100 into the first cavity 214. When the light source 100 is disposed in the first cavity 214, the light emitted from the light source 100 is irradiated toward the inner surface of the first cavity 214, and the inner surface of the first cavity 214 is used as the first light incident surface 211, so that the light emitted from the light source 100 can enter the first light-transmitting portion 210 through the first light incident surface 211. Since the propagation speed of the light in the first cavity 214 is different from the propagation speed of the light in the first light transmitting portion 210, the propagation direction of the light at the first light incident surface 211 is changed, that is, the light is refracted at the first light incident surface 211. The first light-transmitting portion 210 further includes a surface away from the first cavity 214, and when the light propagates from the inside of the first light-transmitting portion 210 to the arc surface, the surface of the first light-transmitting portion 210 away from the first cavity 214 is used as the first light-emitting surface 212, so that the light can be emitted toward the external environment through the first light-emitting surface 212. Since the propagation speed of the light in the first light-transmitting portion 210 is different from the propagation speed in the external environment, the propagation direction of the light at the first light-emitting surface 212 is changed again, that is, the light is refracted again at the first light-emitting surface 212. Based on the above arrangement, the light emitted from the light source 100 can be refracted at the first light incident surface 211 and the first light emitting surface 212, so as to change the propagation direction of the light, and further adjust the irradiation range of the light source 100 through the first light transmission portion 210.

Similarly, a second cavity 224 is formed on the second light-transmitting portion 220. Optionally, an inner side surface of the second cavity 224 is used as the second light incident surface 221, and a surface of the second light transmitting portion 220 away from the second cavity 224 is used as the second light emitting surface 222. Thus, the light emitted from the light source 100 can be refracted at the second light incident surface 221 and the second light emitting surface 222, so as to change the propagation direction of the light, and further adjust the irradiation range of the light source 100 through the second light transmitting portion 220. It should be noted that the principle of projecting light rays by the second light transmission portion 220 is basically the same as the principle of projecting light rays by the first light transmission portion 210, and the description thereof is omitted here.

Alternatively, the first and second light-transmitting portions 210 and 220 may have the same structure.

In the embodiment of the present application, light may be transmitted through a first light path formed by the first light incident surface 211, the first light transmitting portion 210, and the first light exiting surface 212, and light may also be transmitted through a second light path formed by the second light incident surface 221, the second light transmitting portion 220, and the second light exiting surface 222, compared with the conventional lens 200, the lens 200 formed by the first light transmitting portion 210 and the second light transmitting portion 220 in the embodiment of the present application may expand the irradiation range of light, so that the irradiation range of a lamp using the lens 200 is not limited, and the lighting effect of the lamp is greatly improved.

In some embodiments, the first light incident surface 211 is a free-form surface. The free-form surface refers to a surface with the characteristics of no continuous processing and arbitrary traditional processing and forming, is the most complex and frequently encountered curved surface in engineering, and is the free-form surface in the shapes of various parts in the departments of aviation, shipbuilding, automobiles, household appliances, mechanical manufacturing and the like, such as airplane wings or automobile shape curved surfaces, the surfaces of die workpieces and the like. In the embodiment of the present application, the first light incident surface 211 adopts a free-form surface, which can change the shape and curvature of the incident surface of the light ray on the first light transmitting portion 210, so as to change the incident angle of the light ray on the first light transmitting portion 210. Similarly, the second light incident surface 221 may be a free-form surface, which may change the shape and curvature of the incident surface of the light ray on the second light transmitting portion 220, so as to change the incident angle of the light ray on the second light transmitting portion 220.

The first light emitting surface 212 may change the shape and curvature of the light emitting surface of the light ray on the first light transmitting portion 210 by using a free-form surface, so as to change the emitting angle of the light ray on the first light transmitting portion 210. Similarly, the shape and curvature of the exit surface of the light ray on the second light-transmitting portion 220 can be changed by the second light-emitting surface 222 adopting a free-form surface, so as to change the exit angle of the light ray on the second light-transmitting portion 220.

Optionally, in this embodiment of the application, the first light incident surface 211 and the first light emitting surface 212 of the first light transmissive portion 210 both adopt free curved surfaces, and the second light incident surface 221 and the second light emitting surface 222 of the second light transmissive portion 220 both adopt free curved surfaces. According to the law of refraction, the characteristic that the first light transmission part 210 and the second light transmission part 220 of the free curved surface can change the direction of the passing light is utilized, the irradiation direction of the lamp source 100 is purposefully changed, the surface shape and the curvature of the emergent surface and the shape and the curvature of the incident surface of the first light transmission part 210 and the second light transmission part 220 can be changed, the incident angle of the light and the irradiation direction of the refracted light are changed, the irradiation angle, the range and the light distribution of the lamp source 100 are changed, and the ideal light distribution effect is obtained.

In some embodiments, at least one of the first and second light-transmitting portions 210 and 220 is a polarized lens, including specifically that the first light-transmitting portion 210 is a polarized lens, or the second light-transmitting portion 220 is a polarized lens, or both the first and second light-transmitting portions 210 and 220 are polarized lenses. In general, light rays pass through a polarizing lens and then are deflected in a certain direction, thereby changing the irradiation direction and the irradiation range of the light rays, i.e., the light distribution.

Alternatively, one of the first and second light-transmitting portions 210 and 220 is polarized toward a direction away from the other. As shown in fig. 6, a region irradiated with light after passing through the first light transmission portion 210 is a P region, and a region irradiated with light after passing through the second light transmission portion 220 is a Q region. When the first light-transmitting portion 210 and the second light-transmitting portion 220 are both polarized lenses, the first light-transmitting portion 210 can polarize light toward a side away from the second light-transmitting portion 220, and the second light-transmitting portion 220 can polarize light toward a side away from the first light-transmitting portion 210, so that the irradiation range of light can be expanded to a certain extent, and the illumination effect can be improved.

In some embodiments, the extending direction of the first optical axis M is perpendicular to the extending direction of the second optical axis N. Of course, besides being perpendicular to each other, an acute angle, an obtuse angle, etc. may be formed between the two, and in the embodiment of the present application, an included angle between the extending direction of the first optical axis M and the extending direction of the second optical axis N may be determined according to actual situations.

In some embodiments, the first light-transmitting portion 210 has a first base surface 213 connecting the first light incident surface 211 and the first light emitting surface 212, and the first base surface 213 is perpendicular to the first optical axis M. Referring to fig. 3 and 4, the surface of the open end surface of the first cavity 214 is the first base surface 213, and the first base surface 213 is a plane. The first light incident surface 211 may be an arc surface, the first light emitting surface 212 may be an arc surface, the first light incident surface 211 is located in a space surrounded by the first light emitting surface 212, two ends of the first light incident surface 211 are coplanar with two ends of the first light emitting surface 212, and the first base surface 213 correspondingly connects two ends of the first light incident surface 211 with two ends of the first light emitting surface 212, so that the first light incident surface 211, the first base surface 213, and the first light emitting surface 212 together enclose the first light transmission portion 210. Alternatively, the first base surface 213 can be used as a mounting surface for the first light source 110, and the first optical axis M is perpendicular to the first base surface 213.

Similarly, the second transparent portion 220 has a second base surface 223 connected to the second light incident surface 221 and the second light emitting surface 222, and the second base surface 223 is perpendicular to the second optical axis N. With continued reference to fig. 3 and 4, the surface of the open end surface of the second cavity 224 is a second base surface 223, and the second base surface 223 is a plane. The second light incident surface 221 may be an arc surface, the second light emitting surface 222 may be an arc surface, the second light incident surface 221 is located in a space surrounded by the second light emitting surface 222, two ends of the second light incident surface 221 are coplanar with two ends of the second light emitting surface 222, and the second base surface 223 correspondingly connects two ends of the second light incident surface 221 with two ends of the second light emitting surface 222, so that the second light incident surface 221, the second base surface 223, and the second light emitting surface 222 together enclose the second light transmitting portion 220. Alternatively, the second base surface 223 may serve as a mounting surface for the second light source 120, and the second optical axis N is perpendicular to the second base surface 223.

With continued reference to fig. 3 and 4, in some embodiments, the lens 200 further includes a connection portion 230, the connection portion 230 is disposed between the first light-transmitting portion 210 and the second light-transmitting portion 220, and the first light-transmitting portion 210 and the second light-transmitting portion 220 can be connected together through the connection portion 230. Optionally, the connecting portion 230 includes a first side surface, the first side surface is connected to the first base surface 213 and forms an included angle with the first base surface 213, so that a first groove 231 is defined between the first side surface and the first base surface 213. By providing the first groove 231, a space for avoiding position can be formed in the connection region of the first light-transmitting portion 210 and the connection portion 230, and when the first lamp source 110 is installed in the first cavity 214, an installation structure of the first lamp source 110 can be provided at the first groove 231, so as to facilitate installation of the first lamp source 110.

The connecting portion 230 further includes a second side surface, the second side surface is connected to the second base surface 223, and an included angle is formed between the second side surface and the second base surface 223, so that a second groove 232 is defined between the second side surface and the second base surface 223. By providing the second groove 232, a space for avoiding space can be formed in the connection region between the second light-transmitting portion 220 and the connection portion 230, and when the second light source 120 is installed in the second cavity 224, an installation structure of the second light source 120 can be provided at the second groove 232, so as to facilitate installation of the second light source 120.

In some embodiments, the first and second light-transmitting portions 210 and 220 are symmetrically disposed. Referring to fig. 3, the first light transmission portion 210 and the second light transmission portion 220 are symmetrical with respect to the straight line UV, so that a region formed by the light emitted through the first light transmission portion 210 and a region formed by the light emitted through the second light transmission portion 220 may be symmetrical with respect to the straight line UV, thereby forming light spots having the same distribution on a surface opposite to the first light transmission portion 210 and a surface opposite to the second light transmission portion 220, and further improving an irradiation effect.

Of course, in the embodiment of the present application, the first light-transmitting portion 210 and the second light-transmitting portion 220 may also be disposed asymmetrically, that is, the lens 200 is an asymmetric lens, as shown in fig. 4. Whether the lens 200 is symmetrical or not can be selected according to actual requirements, and the embodiment of the present application is not limited.

Referring to fig. 4, in some embodiments, the first transparent portion 210 may have a symmetrical structure. At this time, the two sides of the first light incident surface 211 are symmetrical, the two sides of the first light emitting surface 212 are symmetrical, and the first light incident surface 211 is located in the middle of the space surrounded by the first light emitting surface 212, so that the thicknesses between the two sides of the first light incident surface 211 and the corresponding sides of the first light emitting surface 212 are equal, and thus, the light spot formed by the light emitted after the light is projected through the first light transmitting portion 210 is a symmetrical light spot, so as to meet the requirement of the symmetrical light spot. Certainly, the first light-transmitting portion 210 may also be in an asymmetric structure, and at this time, the first light-incident surface 211 deviates from the middle position of the space surrounded by the first light-emitting surface 212, so that the thicknesses between the two sides of the first light-incident surface 211 and the corresponding sides of the first light-emitting surface 212 are not equal, and thus, a light spot formed by the light emitted after the light is projected through the first light-transmitting portion 210 is an asymmetric light spot, so as to meet the requirement of the asymmetric light spot.

Similarly, the second light-transmitting portion 220 may also be a symmetric structure or an asymmetric structure, which can be specifically referred to as the first light-transmitting portion 210, and the specific structure of the second light-transmitting portion 220 is selected according to actual requirements.

In some embodiments, the lens 200 is an integrally formed structure, which simplifies the manufacturing process of the lens 200 and improves the manufacturing efficiency of the lens 200. Of course, the lens 200 may be manufactured by post-machining, and in the embodiment of the present application, the manufacturing manner is not limited.

In consideration of the fact that the lens 200 needs to refract light, in the embodiment of the present application, the lens 200 is made of a transparent optical material. Alternatively, the lens 200 is made of transparent plastic, transparent silicone, transparent glass, or the like. In the embodiment of the present application, the specific material of the lens 200 is not limited.

In some embodiments, lens 200 may be a stretch-type lens. In general, the structure of the lens 200 can be optimized to some extent by using a stretching type lens, so that light is more uniform, and the illumination effect is improved.

The embodiment of the application also discloses a lamp which comprises a lamp source 100 and the lens 200. Optionally, the light source 100 may be an LED light bulb, an incandescent light bulb, or the like, and light may be emitted by the light source 100 to perform an illumination function. The light source 100 includes a first light source 110 and a second light source 120, at least a portion of the first light source 110 is disposed opposite to the first light incident surface 211, so that light emitted from the first light source 110 irradiates the first light incident surface 211 and enters the first light transmission portion 210 through the first light incident surface 211; the second light source 120 is at least partially disposed opposite to the second light incident surface 221, so that the light emitted from the second light source 120 irradiates the second light incident surface 221 and enters the second light transmission portion 220 through the second light incident surface 221. Based on the above arrangement, the light entering the first light-transmitting portion 210 through the first light-entering surface 211 is transmitted through the first light-transmitting portion 210 and then emitted from the first light-emitting surface 212, so as to illuminate the surface opposite to the first light-transmitting portion 210; the light entering the second light transmissive portion 220 through the second light incident surface 221 is transmitted through the second light transmissive portion 220 and then emitted from the second light emitting surface 222, so as to illuminate the surface opposite to the second light transmissive portion 220. Therefore, the first light-transmitting portion 210 can transmit light emitted from the first light source 110, and the second light-transmitting portion 220 can transmit light emitted from the second light source 120, so that different areas can be illuminated at the same time, thereby improving the visual effect of the illuminated building.

In order to fix the lamp source 100, in the embodiment of the present application, the lamp includes a first fixing plate 310 and a second fixing plate 320. The first fixing plate 310 is disposed on the first light-transmitting portion 210, and optionally, the first fixing plate 310 is attached to the first base surface 213 of the first light-transmitting portion 210. The first light source 110 is disposed on the first fixing plate 310, such that when the first fixing plate 310 is disposed on the first light-transmitting portion 210, the first light source 110 is located in the first cavity 214, so that the light emitted from the first light source 110 can irradiate towards the first light incident surface 211. The first light source 110 can be installed through the first fixing plate 310, and the first cavity 214 can be covered, so that dust, impurities and the like are effectively prevented from entering from the opening of the first cavity 214 and adhering to the first light incident surface 211, the cleanliness of the first light incident surface 211 is further ensured, and the light transmission effect of the first light transmission part 210 is favorably improved.

Similarly, the second fixing plate 320 is disposed on the second light-transmitting portion 220, and optionally, the second fixing plate 320 is attached to the second base surface 223 of the second light-transmitting portion 220. The second light source 120 is disposed on the second fixing plate 320, such that when the second fixing plate 320 is disposed on the second light-transmitting portion 220, the second light source 120 is located in the second cavity 224, and the light emitted by the second light source 120 can be irradiated toward the second light incident surface 221. The second light source 120 can be installed through the second fixing plate 320, and the second cavity 224 can be covered, so that dust, impurities and the like are effectively prevented from entering from the opening of the second cavity 224 and adhering to the second light incident surface 221, cleanliness of the second light incident surface 221 is guaranteed, and the crown effect of the second light transmission portion 220 is improved.

In some embodiments, the first fixing plate 310 may be an aluminum substrate, which reduces the weight of the lamp to some extent, and at the same time has sufficient strength, so that the fixing and mounting effects on the first light source 110 and the covering effect on the first cavity 214 can be ensured. Similarly, the second fixing plate 320 may be an aluminum substrate, which reduces the weight of the lamp to some extent, and at the same time, has sufficient strength, so as to ensure the fixing and mounting functions of the second light source 120 and the covering function of the second cavity 224.

In the embodiment of the application, the lamp can be a wall washer lamp. The wall washing lamp is used for architectural decoration and illumination, can wash the wall surface like water, and can be used for outlining large buildings. Alternatively, the wash light may be mounted in the area where the top wall panel and the side wall 500 are connected. Specifically, the first light-transmitting portion 210 is disposed parallel to the ceiling surface 400 and parallel to the side wall surface 500 in the horizontal direction and is disposed opposite to the ceiling surface 400, and the second light-transmitting portion 220 is disposed parallel to the ceiling surface 400 and parallel to the side wall surface 500 in the horizontal direction and is disposed opposite to the side wall surface 500. Based on above-mentioned setting for the light that first printing opacity portion 210 jetted out shines on ceiling 400, thereby forms the facula on ceiling 400, and the light that second printing opacity portion 220 jetted out shines on side wall surface 500, thereby forms the facula on side wall surface 500, and then has promoted the visual effect of building.

To sum up, in the embodiment of the present application, the light emitting angles can be respectively controlled through the first light transmission portion 210 and the second light transmission portion 220, so as to achieve the effect of simultaneously illuminating two surfaces, and the light spots on the two surfaces can be respectively controlled to meet the requirements of different scenes and lighting, thereby improving the visual sense of the illuminated building.

While the present embodiments have been described with reference to the accompanying drawings, it is to be understood that the invention is not limited to the precise embodiments described above, which are meant to be illustrative and not restrictive, and that various changes may be made therein by those skilled in the art without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (16)

1. A lens (200), comprising: a first light transmission section (210) and a second light transmission section (220) provided in the first light transmission section (210);

the first light-transmitting part (210) is provided with a first cavity (214), the first light-transmitting part (210) comprises a first light incident surface (211) and a first light emitting surface (212), the first light incident surface (211) is the inner side surface of the first cavity (214), and the first light emitting surface (212) is the surface of the first light-transmitting part (210) deviating from the first cavity (214);

the second light-transmitting portion (220) is provided with a second cavity (224), the second light-transmitting portion (220) comprises a second light incident surface (221) and a second light emitting surface (222), the second light incident surface (221) is the inner side surface of the second cavity (224), and the second light emitting surface (222) is the surface of the second light-transmitting portion (220) deviating from the second cavity (224);

the first light transmission part (210) comprises a first optical axis (M), and the second light transmission part (220) comprises a second optical axis (N) which forms an included angle with the first optical axis (M).

2. The lens (200) of claim 1, wherein the first light incident surface (211) is a free-form surface;

and/or the first light-emitting surface (212) is a free-form surface;

and/or the second light incident surface (221) is a free-form surface;

and/or the second light emitting surface (222) is a free-form surface.

3. The lens (200) of claim 1, wherein at least one of the first light-transmitting portion (210) and the second light-transmitting portion (220) is a polarizing lens.

4. The lens (200) according to claim 3, wherein one of the first light-transmitting portion (210) and the second light-transmitting portion (220) is polarized towards a direction away from the other.

5. Lens (200) according to claim 1, characterized in that the direction of extension of the first optical axis (M) is perpendicular to the direction of extension of the second optical axis (N).

6. The lens (200) according to claim 1 or 5, wherein the first light transmitting portion (210) has a first base surface (213) connecting the first light incident surface (211) and the first light emitting surface (212), the first base surface (213) being perpendicular to the first optical axis (M);

and/or the second light-transmitting part (220) is provided with a second base surface (223) connected with the second light incident surface (221) and the second light emitting surface (222), and the second base surface (223) is perpendicular to the second optical axis (N).

7. The lens (200) of claim 6, wherein the lens (200) further comprises a connection portion (230), the connection portion (230) being connected between the first light-transmissive portion (210) and the second light-transmissive portion (220);

connecting portion (230) include first side and second side, first side with first base face (213) are connected and are the contained angle setting, just first side with enclose between first base face (213) and establish into first recess (231), the second side with second base face (223) are connected and are the contained angle setting, just the second side with enclose between second base face (223) and establish into second recess (232).

8. The lens (200) of claim 1, wherein the first light-transmitting portion (210) is symmetrically disposed with respect to the second light-transmitting portion (220).

9. The lens (200) of claim 1, wherein the first light-transmitting portion (210) is a symmetric structure;

and/or the second light transmission part (220) is of a symmetrical structure.

10. The lens (200) of claim 1, wherein the lens (200) is a unitary structure.

11. The lens (200) of claim 1, wherein the lens (200) is a transparent optical material.

12. The lens (200) of claim 1, wherein the lens (200) is a tension type lens.

13. A light fixture, comprising:

a lens (200), the lens (200) being the lens (200) of any one of claims 1 to 12; and

the light source (100), the light source (100) includes a first light source (110) and a second light source (120), the first light source (110) is at least partially arranged opposite to the first light incident surface (211), and the second light source (120) is at least partially arranged opposite to the second light incident surface (221);

the light emitted by the first light source (110) is emitted to the first light incident surface (211), transmitted by the first light transmission part (210) and emitted through the first light emitting surface (212), and the light emitted by the second light source (120) is emitted to the second light incident surface (221), projected by the second light transmission part (220) and emitted through the second light emitting surface (222).

14. A light fixture as claimed in claim 13, characterized in that the light fixture further comprises a first fixture plate (310) and a second fixture plate (320);

the first fixing plate (310) is disposed on the first light transmission portion (210), the first lamp source (110) is disposed on the first fixing plate (310) and located in the first cavity (214), the second fixing plate (320) is disposed on the second light transmission portion (220), and the second lamp source (120) is disposed on the second fixing plate (320) and located in the second cavity (224).

15. A lamp as recited in claim 14, wherein the first fixing plate (310) is an aluminum substrate;

and/or the second fixing plate (320) is an aluminum substrate.

16. A light fixture as claimed in claim 13, wherein the light fixture is a wall washer that is suspended from an area where a ceiling (400) is connected to a side wall (500), the first light-transmitting portion (210) is disposed opposite to the ceiling (400), and the second light-transmitting portion (220) is disposed opposite to the side wall (500).

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