CN120538004A - Lamp and electronic equipment - Google Patents

Abstract

The application provides a lamp and electronic equipment, and belongs to the technical field of intelligent home. The second light-emitting module is used for supplementing light to the face of a user in the first position state, and is close to the outer surface of the first light-emitting module in the second position state, so that the lamp not only provides a conventional lighting function of the first light-emitting module, but also can provide at least an additional face light supplementing function through the second light-emitting module, the first light-emitting module and the second light-emitting module independently emit light to provide lighting or light supplementing for different areas and different directions, and the second position state reduces the whole space occupation of the lamp, keeps the whole of the lamp attractive, and is convenient to store. The user can flexibly adjust the second light-emitting module to the first position state and the second position state, so that the requirements of the user in different scenes are met.

Description

Lamp and electronic equipment

Technical Field

The application relates to the technical field of intelligent home, in particular to a lamp and electronic equipment.

Background

Existing luminaire designs typically provide only a single lighting function, focusing mainly on a certain fixed direction or area. This design has the following problems:

The traditional lamp can only meet basic lighting requirements, lacks diversified functions and cannot adapt to diversified requirements of users in different scenes.

The flexibility is not enough, the structure and the function of the existing lamp are relatively fixed, and a user cannot adjust the use mode of the lamp according to own requirements, so that the application range of the lamp is limited.

The user experience is limited, and the existing lamp has defects when meeting the specific requirements of the user due to the lack of flexibility and multifunctionality, so that the overall use experience is affected.

Disclosure of Invention

The embodiment of the application provides a lamp and electronic equipment, and belongs to the technical field of intelligent home. Specific:

a first aspect of an embodiment of the present application provides a lamp, including:

The first light-emitting module and the second light-emitting module are rotationally connected relative to the first light-emitting module, and the rotation axis L2 of the second light-emitting module is parallel to the extension direction of the first light-emitting module;

The second light-emitting module at least comprises a first position state and a second position state when rotating relative to the first light-emitting module, wherein the second light-emitting module is used for supplementing light to the face of a user when in the first position state and is close to the outer surface of the first light-emitting module when in the second position state;

When the second light-emitting module is used for supplementing light to the face of the user, the optical axis direction of the second light-emitting module is not parallel to the optical axis direction of the first light-emitting module.

In the above technical solution, the first light emitting module has a first light emitting surface, the second light emitting module has a second light emitting surface, and the first light emitting surface is disposed at the bottom of the first light emitting module;

the second light-emitting surface can change the direction along with the rotation of the second light-emitting module;

when the second light emitting module is in the second position state, the second light emitting surface is shielded.

In the above technical solution, when the second light emitting module is in the second position state, the second light emitting surface is hidden between the first light emitting module and the second light emitting module, or the second light emitting surface is hidden in the first light emitting module.

In the above technical solution, the first light emitting module includes:

The first light source, the reflecting piece and the first light outlet cover are arranged in the first lamp housing;

The first light source is arranged at a position deviating from the first light outlet, and light beams emitted by the first light source can be emitted from the first light outlet through reflection of the reflecting piece.

In the above technical solution, the second reflecting member has a straight reflecting surface obliquely disposed in the first lamp housing.

In the above technical solution, the second light emitting module includes:

The surface of the second lamp housing forms a second light emitting surface with a second light emitting opening, and a light guide plate and a second light source are arranged in the second lamp housing;

The second light source is arranged at a position deviating from the second light outlet and corresponds to the side plate surface of the light guide plate.

In the above technical solution, a soft light plate and/or a diffusion plate is further disposed at the second light outlet of the second light emitting module.

In the technical scheme, when the second light-emitting module is opened to a first preset angle, the second light-emitting module is automatically opened, and when the second light-emitting module is closed to a second preset angle, the second light-emitting module is automatically closed.

In the above technical scheme, the lamp further comprises a position sensing module matched with the first light-emitting module and the second light-emitting module for use, and the position sensing module is used for detecting the rotation angle of the second light-emitting module relative to the first light-emitting module.

In the above technical scheme, the position sensing module includes hall sensor and magnet, is equipped with hall sensor on one of first luminous module and the second luminous module, is equipped with magnet on the other, and hall sensor can respond to the magnetic force size of magnet when the second luminous module rotates for first luminous module to the lighting and the extinction of second luminous module are controlled according to the magnetic force size of sensing.

In the technical scheme, the second light-emitting module and/or the first light-emitting module are/is provided with a video acquisition module;

The video acquisition module is shielded when the second light emitting module is in the second position state.

In the above technical scheme, the outer surface of the first light emitting module is further provided with a man-machine interaction area, and the man-machine interaction area is used for identifying external instructions and controlling the first light emitting module and/or the second light emitting module.

In the above technical solution, the outer surface of the first light emitting module has a second light emitting module matching area corresponding to the position of the second light emitting module when the second light emitting module is in the second position state;

the man-machine interaction area is located at a position of the first light-emitting module except for the second light-emitting module matching area.

In the above-described aspect, the first light emitting module is configured as a strip-shaped lamp body, and the second light emitting module is configured as a sheet-shaped lamp body;

the lower surface of the first light-emitting module forms a first light-emitting surface with a first light-emitting opening;

The rotary connection position of the second light-emitting module and the first light-emitting module is positioned at the connection position between the front surface and the upper surface of the first light-emitting module;

the second light-emitting module is close to the front surface of the first light-emitting module when being in the second position state.

In the above technical scheme, the length of the second light emitting module is smaller than that of the first light emitting module, and the second light emitting module is arranged at the middle position of the length direction of the first light emitting module.

In the technical proposal, the lamp also comprises a rotary connecting part, the second light-emitting module is rotatably arranged on the first light-emitting module through the rotary connecting part,

The rotating connecting part comprises a rotating shaft support, a rotating shaft shell and a rotating shaft body, wherein the rotating shaft support is fixed on the first light-emitting module, a shaft hole is formed in the rotating shaft support, the rotating shaft shell is arranged in the shaft hole of the rotating shaft support, one part of the rotating shaft body is rotationally sleeved in the rotating shaft shell, the other part of the rotating shaft body is arranged outside the rotating shaft shell and is fixedly provided with a locking piece, and the locking piece is used for fixing the second light-emitting module and the rotating shaft body together.

In the above technical scheme, a limiting structure is formed between the rotating shaft body and the rotating shaft shell, and the limiting structure is used for limiting the unfolding angle of the second light-emitting module relative to the first light-emitting module.

In the above technical scheme, the lamp further comprises a lamp base, and the first light-emitting module is connected with the lamp base and is installed at the target installation position through the lamp base.

The second aspect of the embodiment of the application provides electronic equipment, which comprises a first light-emitting module used for providing illumination for a table surface and a second light-emitting module used for supplementing light for the face of a user, wherein the second light-emitting module is movably connected relative to the first light-emitting module;

The electronic equipment further comprises a collecting module located on the outer surface of the first light-emitting module or the light-emitting surface of the second light-emitting module, wherein the collecting module can be exposed or shielded when the second light-emitting module is located at different active positions, and the collecting module comprises at least one of an audio collecting module and a video collecting module.

After the technical scheme is adopted, compared with the prior art, the invention has the following beneficial effects:

The second light-emitting module is used for supplementing light to the face of a user in the first position state, and is close to the outer surface of the first light-emitting module in the second position state, so that the lamp not only can provide a conventional lighting function of the first light-emitting module, but also can provide at least an additional facial light supplementing function through the second light-emitting module, and the optical axis direction of the second light-emitting module is not parallel to the optical axis direction of the first light-emitting module in the first position state, so that the first light-emitting module and the second light-emitting module can independently emit light to provide lighting or light supplementing for different areas and different directions, and meanwhile, the second light-emitting module also has the second position state, and is close to the first light-emitting module in the second position state, so that the whole space occupation of the lamp is reduced, the whole lamp is attractive, and the lamp is kept and is convenient to store. The user can flexibly adjust the second light-emitting module to the first position state and the second position state, so that the requirements of the user in different scenes are met. The rotation axis L2 of the second light-emitting module is parallel to the extending direction of the first light-emitting module, the rotation axis direction of the second light-emitting module is defined by the design, and the changing direction of the optical axis of the second light-emitting module is also defined, namely, the second light-emitting module rotates around the extending direction of the first light-emitting module, so that the light supplementing function in different directions is provided.

Drawings

Fig. 1 is a schematic three-dimensional structure of a lamp according to an embodiment of the present application, in which a second light emitting module is in an unfolded state;

fig. 2 is a schematic diagram of a front view structure of a lamp according to an embodiment of the present application, in which a second light emitting module is in an unfolded state;

fig. 3 is a schematic diagram of a rear view structure of a lamp according to an embodiment of the present application, in which a second light emitting module is in an unfolded state;

Fig. 4 is a schematic side view of a lamp according to an embodiment of the present application, in which a second light emitting module is in an unfolded state;

Fig. 5 is a schematic top view of a lamp according to an embodiment of the present application, in which a second light emitting module is in an unfolded state;

Fig. 6 is a schematic diagram of a bottom view of a lamp according to an embodiment of the present application, in which a second light emitting module is in an unfolded state;

fig. 7 is a schematic three-dimensional structure of a lamp according to an embodiment of the present application, in which a second light emitting module is in a folded state;

fig. 8 is a schematic diagram of a front view structure of a lamp according to an embodiment of the present application, in which a second light emitting module is in a folded state;

Fig. 9 is a schematic diagram of a rear view structure of a lamp according to an embodiment of the present application, in which a second light emitting module is in a folded state;

Fig. 10 is a schematic side view of a lamp according to an embodiment of the present application, in which a second light emitting module is in a folded state;

Fig. 11 is a schematic top view of a lamp according to an embodiment of the present application, in which a second light emitting module is in a folded state;

fig. 12 is a schematic bottom view of a lamp according to an embodiment of the present application, in which a second light emitting module is in a folded state;

FIG. 13 is a schematic view of an exploded construction of a rotatable connection according to an embodiment of the present application;

FIG. 14 is a schematic side sectional view of a rotary connection member after assembly in accordance with an embodiment of the present application;

FIG. 15 is an exploded view of a first light emitting module according to an embodiment of the present application;

FIG. 16 is a schematic side sectional view of a first light emitting module according to an embodiment of the present application;

FIG. 17 is a schematic diagram of an exploded structure of a second light emitting module according to an embodiment of the present application;

fig. 18 is a schematic side sectional view of a second light emitting module after assembly according to an embodiment of the present application.

Wherein:

10-first light emitting modules, 101-first light emitting surfaces, 11-acquisition modules, 1 a-first lamp housings, 1 b-first light sources, 1 c-reflecting pieces, 1 d-first light emitting covers, 1 e-main control boards and 1 f-switching circuit boards;

20-second light emitting modules, 201-second light emitting surfaces, 2 a-second lamp shells, 2a 1-bottom shells, 2a 2-surface shells, 2 b-light guide plates, 2 c-second light sources, 2 d-second light emitting covers, 2 e-reflective paper and 2 f-foam;

30-rotating connecting parts, 31-rotating shaft brackets, 32-rotating shaft shells, 321-stop surfaces, 33-rotating shaft bodies, 331-positioning surfaces and 34-locking pieces;

40-lamp base, 401-bayonet, 40 a-connecting part and 40 b-counterweight part.

Detailed Description

Embodiments of the present invention are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative and intended to explain the present invention and should not be construed as limiting the invention.

Throughout the specification and claims, the following terms have at least the meanings explicitly associated herein, unless the context dictates otherwise. The meanings identified below are not necessarily limiting terms, but merely provide illustrative examples of terms.

In the description of the present invention, the phrase "in one embodiment" does not necessarily refer to the same embodiment, although it may. Similarly, the phrase "in some embodiments" as used herein, when used multiple times, does not necessarily refer to the same embodiment, although it may. As used herein, the term "or" is an inclusive "or" operator and is equivalent to the term "and/or" unless the context clearly dictates otherwise. The term "based on" is not exclusive and allows for being based on additional factors not described, unless the context clearly dictates otherwise. The term "exemplary" is used herein to mean "serving as an example, instance, or illustration. Any embodiment described herein as "exemplary" is not necessarily to be construed as preferred or advantageous over other embodiments. The scope of the invention is limited only by the scope of the appended claims, and any examples set forth in this specification are not intended to be limiting, but merely set forth some of the many possible embodiments of the claimed invention. The various embodiments provided by the present invention should not be construed as limiting the scope of the invention.

In the description of the present invention, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the present invention, the meaning of "a plurality" is two or more, unless explicitly defined otherwise.

In the present invention, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed, mechanically connected, electrically connected, directly connected, indirectly connected via an intervening medium, or in communication between two elements or in an interaction relationship between two elements. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art according to the specific circumstances.

In the present invention, unless expressly stated or limited otherwise, a first feature "above" or "below" a second feature may include both the first and second features being in direct contact, as well as the first and second features not being in direct contact but being in contact with each other through additional features therebetween. Moreover, a first feature being "above," "over" and "on" a second feature includes the first feature being directly above and obliquely above the second feature, or simply indicating that the first feature is higher in level than the second feature. The first feature being "under", "below" and "beneath" the second feature includes the first feature being directly under and obliquely below the second feature, or simply means that the first feature is less level than the second feature.

Aiming at the problem that the existing lighting equipment can only provide a single lighting function and mainly concentrate on the lighting of a desktop or other horizontal surfaces, the embodiment of the application provides the multifunctional, flexible and user-friendly lighting equipment, and the defects in the prior art are overcome by integrating a main light lamp, a supplementary light lamp, a plurality of sensors and intelligent control functions.

For example, when the desk is used in a home environment, the main light lamp provides uniform desktop illumination, the light supplementing lamp can provide additional light according to requirements, so that a user can obtain comfortable illumination when reading or writing, for example, when the desk is used in an office environment, the main light lamp provides stable desktop illumination, so that the user can obtain uniform light when conducting document processing, writing or other desktop work, the light supplementing lamp can be adjusted to a proper angle, the face of the user can be illuminated, so that a clear image can be obtained in a video conference, for example, when the desk is used in an education environment, the light supplementing lamp can be adjusted to a proper angle, the face of a student can be illuminated, so that a clear video effect can be obtained in an online learning process, and the main light lamp provides uniform desktop illumination, so that the student can obtain comfortable illumination when reading or writing, and in addition, the light supplementing lamp can also be independently used by the user when only providing soft light and weak light.

Specifically, as shown in fig. 1to 18, a first aspect of the embodiment of the present application provides a lamp, including:

a first light emitting module 10 and a second light emitting module 20;

Wherein:

The first light-emitting module 10 has an illumination function, and the second light-emitting module 20 has a light supplementing function;

The second light emitting module 20 is movably disposed on the first light emitting module.

The first light-emitting module 10 provides illumination and the second light-emitting module 20 provides light supplement, so that the lamp not only provides a main illumination function, but also provides an additional light supplement function through the second light-emitting module, and the second light-emitting module is movably connected to the first light-emitting module, so that light supplement effects of different angles and different positions can be realized. For example, the first light emitting module 10 can be used for illuminating a desktop or other working area to meet the requirements of a user when reading, writing or performing desktop work, and the second light emitting module 20 can be used for illuminating the face or other specific area of the user, so that the requirements of video call, makeup or performing fine work can be met, and more usage scenes and user requirements can be met.

It should be noted that, in some specific usage scenarios, the first light emitting module 10 may also have a light supplementing effect, and the second light emitting module 20 may also have a lighting effect. Of course, in an ideal usage scenario, the first light emitting module 10 is used for illumination, and the second light emitting module 20 is used for light supplement.

For example, when a user performs a video call in front of a desk, the first light emitting module 10 of the lamp provides uniform desktop illumination, so as to ensure soft background light and reduce shadows, while the second light emitting module 20 is adjusted to a proper angle to directly illuminate the face of the user, so as to ensure sufficient and uniform facial light of the user in the video call and improve video quality.

Further, in some possible embodiments, the first light emitting module 10 and the second light emitting module 20 are configured such that the optical axes of the first light emitting module 10 and the second light emitting module 20 are not parallel when the two light emitting modules provide illumination and the second light emitting module 20 provides facial light supplement.

The optical axis represents the reference direction of the light emitted by the light-emitting module. This design enables the first light emitting module 10 and the second light emitting module 20 to independently provide light rays in different directions without interfering with each other. For example, the optical axis of the first light emitting module 10 may be vertically downward or obliquely forward for illuminating a desk or other horizontal surface to meet the requirements of a user when reading, writing or performing desk work, and the optical axis of the second light emitting module 20 may be obliquely upward, obliquely downward or forward for illuminating a face or other specific area of the user when light is supplemented, so as to meet the requirements of video call, makeup or performing fine work.

Specifically, the second light emitting module 20 is rotatably connected with respect to the first light emitting module 10, and the rotation axis L2 of the second light emitting module 20 is parallel to the extending direction of the first light emitting module 10, or based on the example of fig. 1, it may be understood that the rotation axis L2 of the second light emitting module 20 is parallel to the central axis L1 of the first light emitting module 10;

The second light emitting module 20 at least comprises a first position state and a second position state when rotating relative to the first light emitting module 10, wherein the second light emitting module 20 is used for supplementing light to the face of the user when in the first position state and is close to the outer surface of the first light emitting module 10 when in the second position state;

Wherein the optical axis direction of the second light emitting module 20 is not parallel to the optical axis direction of the first light emitting module 10 when the second light emitting module 20 is used for supplementing light to the face of the user.

The second light emitting module 20 in the embodiment of the application is used for supplementing light to the face of a user in the first position state, and is close to the outer surface of the first light emitting module 10 in the second position state, so that the lamp not only provides the conventional lighting function of the first light emitting module 10, but also can provide at least the additional facial light supplementing function through the second light emitting module 20, and the optical axis direction of the second light emitting module 20 is not parallel to the optical axis direction of the first light emitting module 10 in the first position state, so that the first light emitting module 10 and the second light emitting module 20 independently emit light to provide lighting or light supplementing for different areas and different directions, and meanwhile, the second light emitting module 20 also has the second position state, and is close to the first light emitting module 10, thereby reducing the whole space occupation of the lamp, keeping the whole beautiful appearance of the lamp and being convenient for storage. The user can flexibly adjust the second light emitting module 20 to the first position state and the second position state, so as to meet the requirements of the user in different scenes.

The rotation axis L2 of the second light emitting module 20 is parallel to the extending direction of the first light emitting module 10, and this design defines the rotation axis direction of the second light emitting module 20, and also defines the changing direction of the optical axis of the second light emitting module 20, that is, rotates around the extending direction of the first light emitting module 10, so as to provide the light supplementing function in different directions.

It should be noted that, in the embodiment of the present application, the second light emitting module 20 may be used for supplementing light to the face of the user when in the first position state. In fact, the second light emitting module 20 may have a plurality of angles during the rotation relative to the first light emitting module 10, wherein when the second light emitting module 20 is used for supplementing light to the face of the user, it can be understood that the second light emitting module 20 is in the first position state. It is understood that the rotation angle of the second light emitting module 20 in the first position state may be different for different usage scenarios and different users. As an example, when the second light emitting module 20 is unfolded to a state as shown in fig. 1 with respect to the first light emitting module 10, the second light emitting module 20 at this time is in a first position state capable of supplementing light to the face of the user, i.e., a face light supplementing state.

It should be noted that, in the embodiment of the present application, the second light emitting module 20 is close to the outer surface of the first light emitting module 10 when in the second position state, and this design makes the second light emitting module 20 able to be close to the first light emitting module 10, so that the space occupation is small in this state, and the whole lamp is more compact, and is convenient for storage, packaging, etc. For example, when the light supplementing function is not used, the user can fold the second light emitting module 20 to be closely attached to the first light emitting module 10, so that the space is saved, and the portable and storage are convenient. It should be noted that, the term "close to" in the embodiment of the present application may refer to that the second light emitting module 20 is directly contacted with the outer surface of the first light emitting module 10, or that the second light emitting module 20 is very close to the outer surface of the first light emitting module 10 in space but not directly contacted.

It should be noted that, the first position state is a state that the second light emitting module 20 is used for facial light supplement, and the second position state is a state that the second light emitting module 20 is close to the outer surface of the first light emitting module 10, but it should not be excluded that in some embodiments, the second light emitting module 20 may be close to the outer surface of different sides of the first light emitting module 10 during rotation, where the second light emitting module 20 is close to one outer surface of the first light emitting module 10 for facial light supplement, and belongs to the first position state, and the second position state is close to the other outer surface of the first light emitting module 10.

As in the examples of fig. 1-12, the rotational connection position of the second light emitting module 20 and the first light emitting module 10 is located at the engagement position of the upper surface and the front surface of the first light emitting module 10, and the second light emitting module 20 is rotatable to, for example, the position shown in fig. 1 for supplementing the face, which is the first position state, and when the second light emitting module 20 is rotated to, for example, the position shown in fig. 7, close to the front surface of the first light emitting module 10, which is the second position state.

In an embodiment not shown, the rotational connection position of the second light emitting module 20 and the first light emitting module 10 is located on the upper surface of the first light emitting module 10, the second light emitting module 20 can be rotated to a vertical or inclined forward position for supplementing light to the face, and the state is a first position state, and when the second light emitting module 20 is rotated to be close to the upper surface of the first light emitting module 10, the state is a second position state.

In another embodiment, not shown, the rotational connection position of the second light emitting module 20 and the first light emitting module 10 is located at the connection position of the upper surface and the front surface of the first light emitting module 10, and the second light emitting module 20 can be rotated to, for example, the position shown in fig. 1 for supplementing the face, and the state is the first position state, and when the second light emitting module 20 is rotated to be close to the upper surface of the first light emitting module 10, the state is the second position state.

In another embodiment, not shown, the rotational connection position of the second light emitting module 20 and the first light emitting module 10 is located at the connection position of the upper surface and the front surface of the first light emitting module 10, the second light emitting module 20 can rotate to be close to the front surface of the first light emitting module 10, at this time, a light outlet is formed on the front surface of the second light emitting module 20 for supplementing light to the face, and the state is the first position state, and when the second light emitting module 20 rotates to be close to the upper surface of the first light emitting module 10, the state is the second position state.

Further, in some possible embodiments, the first light emitting module 10 has a first light emitting surface 101, the second light emitting module 20 has a second light emitting surface 201, and the first light emitting surface 101 is disposed at the bottom of the first light emitting module 10;

the second light emitting surface 201 can change the orientation along with the rotation of the second light emitting module 20;

The second light emitting surface 201 is shielded when the second light emitting module 20 is in the second position state.

As in the example of fig. 1-12, when the second light emitting module 20 is in the unfolded state, the second light emitting surface 201 of the second light emitting module 20 may be located or partially located above the top of the first light emitting module 10, and the arrangement enables the light rays of the first light emitting module 10 and the second light emitting module 20 to illuminate different directions and areas, thereby providing a more comprehensive illumination effect. For example, the first light emitting surface 101 at the bottom of the first light emitting module 10 is mainly used for illuminating a desktop or other horizontal surfaces to meet the requirements of a user when reading, writing or performing desktop work, while the second light emitting surface 201 of the second light emitting module 20 in an unfolded state can be located or partially located above the top of the first light emitting module 10 and is mainly used for illuminating the face or other specific areas of the user to meet the requirements of the user when video call, makeup or performing fine work, so that the overlapping and reflection of light rays are reduced, and the uniformity and definition of the lighting effect are improved.

When the second light emitting module 20 is in the second position state, the second light emitting surface 201 of the second light emitting module 20 can face and be close to the outer surface of the first light emitting module, which is not the first light emitting surface 101, and the design enables the second light emitting module 20 to be closely attached to the first light emitting module 10 when not in use, so that space occupation is reduced, the whole lamp is more compact, and the lamp is convenient to store. For example, when the user only needs to illuminate the first light emitting module 10, the second light emitting module 20 can be folded and stored, so that the normal use of the first light emitting module 10 is not interfered. The compact design not only saves space, but also is convenient to carry and store, and improves the portability of the lamp. Meanwhile, in the storage state, the second light-emitting surface 201 of the second light-emitting module 20 is protected by the outer surface of the first light-emitting module 10, so that the risk of damage to the second light-emitting surface 201 in the non-use state is reduced. For example, in the moving or storing process of the lamp, the second light emitting surface 201 of the second light emitting module 20 is shielded by the outer surface of the first light emitting module 10, so that dust, scratches or other physical damages are avoided, the service life of the second light emitting module 20 is prolonged, and the overall attractiveness of the lamp is maintained. It should be noted that, in the embodiment of the present application, the "close to" may refer to that the second light emitting surface 201 is directly contacted with the outer surface of the first light emitting module, or that the second light emitting surface 201 is very close to but not directly contacted with the outer surface of the first light emitting module in space.

Preferably, the extending direction of the first light emitting module 10 is parallel to the first light emitting surface 101 of the first light emitting module 10, and in the embodiment of the present application, the extending direction of the first light emitting module 10 is parallel to the first light emitting surface 101 of the first light emitting module 10, so that the light of the first light emitting module 10 can be ensured to be stably irradiated to a predetermined area, and uniformity and consistency of lighting effects are improved. For example, the light of the first light emitting module 10 is mainly irradiated downwards to illuminate a desktop or other horizontal surfaces, so as to ensure uniform light distribution, and meet the requirements of users when reading, writing or performing desktop work.

It should be noted that the "parallel" mentioned in the embodiments of the present application does not require complete parallelism, but only "parallel within the range of manufacturing and assembly errors".

As shown in the example of fig. 1 to 12, the second light emitting module 20 is close to the front surface of the first light emitting module 10 in the second position, and the rotation position thereof is located at the engagement position of the upper surface and the front surface of the first light emitting module 10. However, in some embodiments, which are not shown, the second light emitting module 20 may be disposed close to the upper surface or the upper surface and the front surface of the first light emitting module 10 in the second position, and the rotation position may be disposed at the upper surface position or the front surface position or the connection position between the front surface and the upper surface of the first light emitting module 10 or other installation positions capable of realizing the relative rotation.

Further, in some possible embodiments, when the second light emitting module 20 is in the second position state, the second light emitting surface 201 is hidden between the first light emitting module 10 and the second light emitting module 20, or the second light emitting surface 201 is hidden in the first light emitting module 10.

In the embodiment of the application, the second light emitting surface 201 on the second light emitting module 20 is hidden between the first light emitting module 10 and the second light emitting module 20 or hidden in the first light emitting module 10 when the second light emitting module 20 is in the second position state of the non-light supplementing state. The design enables the second light-emitting module 20 to be attached to the first light-emitting module 10 in a non-light supplementing state, space occupation is reduced, and the whole lamp is more compact. For example, when the light supplementing function is not used, the user can fold the second light emitting module 20 to hide the second light emitting surface 201 between the first light emitting module 10 and the second light emitting module 20, so that the space is saved, the carrying and the storage are convenient, and meanwhile, the design also protects the second light emitting surface 201 from dust, scratches or other physical damages when the light supplementing function is not used.

Further, in some possible embodiments, the first light emitting module 10 and the second light emitting module 20 have the following associated matching structure:

Specifically, the first light emitting module 10 is provided with a first lamp housing 1a and a first light source 1b disposed in the first lamp housing 1 a;

Specifically, the second light emitting module 20 includes a second lamp housing 2a and a second light source 2c disposed in the second lamp housing 2a, where the second lamp housing 2a is disposed on the first lamp housing 1a in a reversible manner;

When the second light emitting module 20 is in the non-light supplementing state, the inner side surface of the second lamp housing 2a covers the side surface of the first lamp housing 1a, which is not the first light emitting surface side. The inner side of the second lamp housing 2a is the side where the second light emitting surface 201 is located. As shown in fig. 7-12, when the second light emitting module 20 is in the non-light supplementing state, the inner side surface of the second lamp housing 2a covers the front surface of the first lamp housing 1 a. However, in some embodiments, which are not shown, the inner side surface of the second lamp housing 2a may be disposed to cover the upper surface or the upper surface and the front surface of the first lamp housing 1a when the second light emitting module 20 is in the non-light supplementing state.

Further, in some possible embodiments, the side surface of the first lamp housing 1a, which is not the first light-emitting surface side, is provided with a groove adapted to the shape of the second lamp housing 2a, and when the second lamp housing 2a covers the side surface of the first lamp housing 1a, which is not the first light-emitting surface side, the second lamp housing 2a is embedded in the groove.

It is further preferred that the outer surface of the second lamp housing has a shape adapted to the surface of the first lamp housing, and that when the second lamp housing 2a is embedded in the groove, the outer surface of the second lamp housing 2a and the outer surface of the first lamp housing 1a form a smooth plane.

In the embodiment of the application, the second lamp housing 2a covers the side surface of the first lamp housing 1a, which is not on the first light emitting surface side, in the non-light supplementing state. The design enables the second light-emitting module 20 to be closely attached to the first light-emitting module 10 in a non-light supplementing state, space occupation is reduced, and the whole lamp is more compact. Meanwhile, the second light emitting surface 201 is protected from dust, scratches or other physical damages in the non-light supplementing state. The second lamp housing 2a covers the side surface of the first lamp housing 1a, which is not on the first light-emitting surface side, in the non-light-supplementing state, and the outer surface of the second lamp housing 2a and the outer surface of the first lamp housing 1a form a smooth plane, so that the use experience of a user is remarkably improved. When the user does not need light filling, after the second light-emitting module 20 is folded, the overall appearance of the lamp is more concise, and the use satisfaction of the user is improved. The side of the first lamp housing 1a, which is not on the first light-emitting surface side, is provided with a groove matched with the shape of the second lamp housing 2a, and the second lamp housing 2a is embedded in the groove, so that the overall appearance of the lamp is simpler after the second light-emitting module 20 is folded.

Further, in some possible embodiments, the second light emitting module 20 is automatically turned on when the second light emitting module 20 is turned on to the first preset angle, and the second light emitting module 20 is automatically turned off when the second light emitting module 20 is turned off to the second preset angle.

Preferably, the second lamp housing and the second light source of the second light emitting module 20 are configured such that the second light source 2c is automatically turned on when the second lamp housing 2a is turned on to a first preset angle, and the second light source 2c is automatically turned off when the second lamp housing 2a is turned off to a second preset angle.

Preferably, a position sensor is arranged between the second lamp housing 2a and the first lamp housing 1a and used for detecting the angle of the second lamp housing 2a relative to the first lamp housing 1a, and the design realizes the automatic opening and closing of the second light source 2c and improves the convenience and the intelligent level of use. For example, when the user opens the second lamp housing 2a to the first preset angle, the second light source 2c is automatically turned on to provide light supplement, and when the user closes the second lamp housing 2a to the second preset angle, the second light source 2c is automatically turned off to avoid unnecessary energy waste. A position sensor is arranged between the second lamp housing 2a and the first lamp housing 1a and is used for detecting the angle and/or distance of the second lamp housing 2a relative to the first lamp housing 1a, and the design realizes accurate detection of the angle of the second lamp housing 2a through the position sensor, so that the second light source 2c is ensured to be turned on or turned off at the correct time. For example, the position sensor can detect the angle and/or distance change of the second lamp housing 2a in real time, so that the second light source 2c is automatically turned on when the first preset angle and/or distance is opened, and the second light source 2c is automatically turned off when the second preset angle and/or distance is closed, and the design ensures that the second light source 2c only works when needed, so that unnecessary energy consumption is avoided, and the energy utilization efficiency of the lamp is improved.

Further, in some possible embodiments, the light fixture further includes a position sensing module that is used in cooperation with the first light emitting module 10 and the second light emitting module 20, and the position sensing module is used for detecting a rotation angle of the second light emitting module 20 relative to the first light emitting module 10.

Further, in some possible embodiments, the position sensing module includes a hall sensor and a magnet, one of the first light emitting module 10 and the second light emitting module 20 is provided with the hall sensor, the other is provided with the magnet, and the hall sensor can sense the magnetic force of the magnet when the second light emitting module 20 rotates relative to the first light emitting module 10, and controls the second light emitting module 20 to be turned on or off according to the sensed magnetic force.

It can be seen that, in the embodiment of the present application, the second light emitting module 20 is turned on and off by the angle and/or distance of the opening, and specifically, the opening and closing can be achieved by the cooperation of the hall sensor and the magnet. Preferably, a hall sensor is disposed in the first light emitting module 10, and a magnet is disposed in the second light emitting module 20, so that when the second light emitting module rotates to a certain angle and/or distance, the hall sensor will not detect magnetic force lines of the magnet, and will turn on the second light emitting module 20, otherwise, the second light emitting module 20 is turned off to a certain angle and/or distance, and the hall sensor will detect magnetic force, and then turn off the second light emitting module 20. However, in some alternative embodiments, such a mating arrangement of "hall sensor + magnet" may be substituted for a travel switch and/or photo-inductive sensor, etc.

Through the design, the accurate automatic control of the second light-emitting module 20 is realized, the second light-emitting module 20 is ensured to be started only when needed, and the convenience and the intelligent level of use are improved. For example, when the user expands the second light emitting module 20 to an angle greater than 30 °, the hall sensor senses the magnetic force change of the magnet, and the circuit is automatically turned on, so that the second light emitting module 20 is turned on. When the user folds the second light emitting module 20 to an angle smaller than 30 degrees, the Hall sensor senses the magnetic force change of the magnet, the circuit is automatically disconnected, and the second light emitting module 20 is closed.

Further, in some possible embodiments, a video capture module is provided on the second light emitting module 20 and/or on the first light emitting module 10;

the video capture module is shielded when the second light module 20 is in the second position state.

Preferably, the video acquisition module comprises a camera module, the camera module is arranged on the side surface of the first lamp housing 1a, which is not the first light-emitting surface, and when the second lamp housing 2a is covered on the side surface of the first lamp housing 1a, which is not the first light-emitting surface, the camera module is also covered by the second lamp housing 2 a;

Or, the camera module is disposed on the inner side surface of the second lamp housing 2a, and when the second lamp housing 2a covers the side surface of the first lamp housing 1a, which is not the first light emitting surface side, the camera module is sandwiched between the second lamp housing 2a and the first lamp housing 1 a;

In the embodiment of the application, the camera module is shielded when the second lamp housing 2a is covered, and the camera module is automatically shielded when the second lamp housing 2a is covered by the camera module, so that the privacy of a user is ensured to be protected. For example, when the user does not need to use the camera module, the second lamp housing 2a can be folded to cover the side surface of the first lamp housing 1a, and the camera module is shielded, so that privacy leakage is avoided. The camera module is arranged on the side surface of the first lamp housing 1a, which is not the first light emitting surface, or the inner side surface of the second lamp housing 2a, and the camera module can be skillfully integrated in the lamp, so that the space occupation is reduced, and the whole lamp is more compact.

In some other embodiments, the camera module is provided with a movable shutter, such as a dial, flip, etc., which may be manually or automatically closed when the camera module is not required to be adapted to protect privacy.

Further, in some possible embodiments, the second lamp housing 2a and the camera module are configured such that the camera module is turned on when the second lamp housing 2a is turned on to a first preset angle and the camera module is turned off when the second lamp housing 2a is turned off to a second preset angle.

Wherein the second lamp housing 2a can be opened and/or closed by a user control and/or the second lamp housing 2a is designed to have a linkage effect with the first lighting module 10 such that the second lamp housing 2a is opened in linkage when the first lighting module 10 is controlled to project light to the illumination area.

The design realizes the automatic opening and closing of the camera module, and improves the convenience and the intelligent level of use. For example, when the user opens the second lamp housing 2a, the camera module is automatically opened, the user does not need to manually operate, the use efficiency is improved, and when the user closes the second lamp housing 2a, the camera module is automatically closed, so that unnecessary energy waste is avoided.

Further, in some possible embodiments, the light fixture is further provided with a first sensor and/or a second sensor and/or a third sensor, wherein the first sensor is used for detecting ambient brightness to control on and light emitting parameters of the first light source 1b and/or the second light source 2c, the second sensor is used for detecting whether a user exists in a preset range of the light fixture to control on of the second light housing 2a, the second light source 2c and/or the camera module, and the third sensor is used for detecting illuminance of a face of the user to control light supplementing parameters of the second light source 2 c.

The first sensor in the embodiment of the present application is used for detecting the ambient brightness to control the on and the light emitting parameters of the first light source 1b and/or the second light source 2 c. This design enables automatic turning on and brightness adjustment of the first light source 1b and/or the second light source 2c, improving the convenience and level of intelligence of use. For example, when the ambient light is dark, the first sensor detects low brightness, the first light source 1b and/or the second light source 2c are/is automatically turned on and adjusted to proper brightness, and when the ambient light is bright, the first sensor detects high brightness, the brightness of the first light source 1b and/or the second light source 2c is/are automatically reduced or turned off, and excessive illumination is avoided.

The second sensor is used for detecting whether a user exists in the preset range of the lamp or not so as to control the second lamp housing 2a, the second light source 2c and/or the camera module to be started, and the design realizes automatic detection of the existence of the user and improves the convenience and the intelligent level of use. For example, when a user enters a preset range of the lamp, the second sensor detects that the user exists, the second lamp housing 2a is automatically opened, the second light source 2c and/or the camera module are/is started, and when the user leaves the preset range of the lamp, the second sensor detects that the user does not exist, the second lamp housing 2a is automatically closed, the second light source 2c and/or the camera module are/is closed, and unnecessary energy waste is avoided.

The third sensor in the embodiment of the present application is used for detecting the illuminance of the face of the user to control the light supplementing parameter of the second light source 2 c. The design realizes accurate detection of the illuminance of the face of the user and automatic adjustment of the light supplementing intensity, and improves the comfort and uniformity of the light supplementing effect. For example, when the illuminance of the face of the user is insufficient, the third sensor detects low illuminance and automatically increases the light supplementing intensity of the second light source 2c, and when the illuminance of the face of the user is sufficient, the third sensor detects high illuminance and automatically reduces or turns off the light supplementing of the second light source 2c, thereby avoiding excessive light supplementing.

Further, in some possible embodiments, a collection module is disposed on the second light emitting module 20 and/or the first light emitting module 10, where the collection module includes an audio collection module and/or a video collection module;

Preferably, the audio acquisition module at least comprises a microphone, and the video acquisition module at least comprises a camera;

preferably, the side surface of the first light emitting module 10 is provided with the collecting module 11, and when the second light emitting module 20 is in the folded non-light supplementing state, the collecting module 11 is shielded between the second light emitting module 20 and the first light emitting module 10.

Further preferably, the design of the camera can be 1 RGB camera+1 IR camera, wherein the RGB camera is used for video shooting, and the IR infrared camera is used for face recognition, such as realizing Windows Hello unlocking function by matching with a computer, and can also be used for assisting shooting at night/when the light environment is not good.

As can be seen from the above description, the collecting module 11 is shielded when the second light emitting module 20 is in the folded non-light supplementing state. This design automatically shields the acquisition module 11 when the second light emitting module 20 is folded, ensuring that the user privacy is protected. For example, when the user does not need to use the audio or video acquisition function, the second light emitting module 20 is folded, the acquisition module 11 is shielded, the camera and the microphone cannot work, the risk of privacy disclosure is avoided, the control of the user on the privacy is obviously enhanced, and the safety and the reliability of the lamp are improved.

In the embodiment of the application, the acquisition module 11 is integrated on the inner surface of the first light emitting module 10 and/or the second light emitting module 20. The design integrates the audio and video acquisition functions into the lamp, reduces the number of devices which are required to be additionally purchased and installed by a user, and improves the functionality and convenience of the lamp. For example, the integrated microphone can be used for voice input, the camera can be used for video call, so that the lamp becomes a multifunctional intelligent device, and the integrated design not only improves the user experience, but also enables the lamp to be more concise and attractive.

It can be seen that the automatic shielding function and the integrated design of the acquisition module 11 significantly improve the use experience of the user. The user does not need to manually operate the switch of the acquisition module 11, and can realize the starting or stopping of the acquisition module 11 by only adjusting the position of the second light-emitting module 20. For example, when a video call is made, the user can expand the second light emitting module 20, the acquisition module 11 is automatically started, and the camera and the microphone start to work. When the acquisition module 11 is not needed, the user can fold the second light emitting module 20, the acquisition module 11 is automatically shielded, and the camera and the microphone stop working.

Further, in some possible embodiments, the lamp further comprises a detector and a controller, wherein the detector is used for detecting whether a movable object exists in a region away from the preset range of the lamp, and the controller is used for controlling the on-off of the first light emitting module 10 according to the detection result of the detector, and/or controlling the on-off of the second light emitting module 20 according to the detection result of the detector;

And/or

The first light emitting module 10 and/or the second light emitting module 20 are provided with a light sensor and a controller, the light sensor is used for acquiring the light intensity of the environment where the lamp is located when the first light emitting module 10 and/or the second light emitting module 20 are turned on, and the controller is used for adjusting the illumination intensity of the first light emitting module 10 and/or the illumination intensity of the second light emitting module 20 according to the light intensity.

According to the embodiment of the application, the detector and the controller are arranged to realize automatic control of the lamp, the intelligent control of the lamp is realized through the design, the first light-emitting module 10, the second light-emitting module 20 and the acquisition module 11 can be automatically opened or closed according to the activities of a user, and the convenience and the intelligent level of use are improved. For example, when a user enters a preset range of the lamp, the distance sensor detects a movable object, and the controller automatically turns on the first light emitting module 10 or the second light emitting module 20 to provide illumination. When the user leaves the preset range of the lamp, the controller automatically turns off the lamp, so that unnecessary energy waste is avoided.

According to the embodiment of the application, the automatic adjustment of illumination intensity is realized by arranging the detector and the controller, and the design can automatically adjust the illumination intensity of the first light-emitting module 10 and the second light-emitting module 20 according to the intensity of ambient light, so that a user is ensured to always obtain a comfortable illumination effect. For example, when the ambient light is darker, the controller automatically increases the illumination intensity of the first light emitting module 10 and the second light emitting module 20, providing brighter illumination. When the ambient light is brighter, the controller automatically reduces the illumination intensity of the first light emitting module 10 and the second light emitting module 20, so as to avoid discomfort caused by the too strong light to the user.

Therefore, the intelligent illumination control design and the self-adaptive illumination intensity adjustment design enable the lamp to be multifunctional intelligent equipment, not only meets the basic illumination requirements of users, but also provides intelligent control and environment perception functions, and the practicality and convenience of the lamp are improved. For example, in a smart home environment, a luminaire may be linked with other smart devices, enabling more complex automation scenarios. In an office environment, the lamp can be automatically adjusted according to activities of users and ambient light, and working efficiency is improved.

Preferably, the above-mentioned detector may be a radar sensor mounted in the first light emitting module 10 and/or the second light emitting module 20 for detecting whether a person is present within a certain distance. The radar sensor can be used for realizing the starting of people, the automatic closing of people walking, and the privacy protection and the automatic control.

Further, in some possible embodiments, the outer surface of the first light emitting module 10 is further provided with a human-computer interaction area 12, and the human-computer interaction area 12 is used for identifying external instructions and controlling the first light emitting module 10 and/or the second light emitting module 20.

Preferably, the human-computer interaction area 12 is used for identifying external instructions and controlling the lamp. For example, the human-computer interaction region 12 may be configured to control on, off, and illumination parameters of the first light emitting module 10 and/or the second light emitting module 20, where the illumination parameters include at least one of illumination brightness, illumination color temperature, and illumination on/off. As another example, the human interaction region 12 may also be used to turn on, off the acquisition module 11, sensors, detectors, etc.

By the design, a convenient user control mode is provided, and a user can directly adjust the lighting parameters of the lamp through the human-computer interaction area 12, so that the convenience and the flexibility of use are improved. For example, the user can quickly adjust the brightness of the first light emitting module 10 and the second light emitting module 20 by touching a button or a slider on the man-machine interaction area 12, and the user can select different color temperature modes through the man-machine interaction area 12 so as to adapt to different use scenes, such as reading, working or relaxing. For example, the user can adjust the brightness to be high and the color temperature to be warm to reduce eye fatigue while reading, and for example, the user can adjust the brightness to be low and the color temperature to be cool while relaxing to create a comfortable atmosphere. Specifically, the human-computer interaction area may be provided with a control button or a slider to implement the above-mentioned adjustment operation.

Further, in some possible embodiments, the outer surface of the first light emitting module 10 has a second light emitting module mating region corresponding to the position of the second light emitting module 20 when the second light emitting module 20 is in the second position state;

The man-machine interaction area 12 is located at a position of the first light emitting module 10 except for the second light emitting module matching area.

Preferably, the man-machine interaction area 12 is located at one side or two sides of the length direction of the second light emitting module matching area.

In the embodiment of the application, the outer surface of the first light emitting module 10 is provided with the second light emitting module matching area for matching with the second light emitting module 20 when the second light emitting module 20 is folded, so that the second light emitting module 20 can be close to the first light emitting module 10 when the second light emitting module 20 is folded, the space occupation is reduced, and the whole lamp is more compact. For example, when the second light emitting module 20 is folded, the second light emitting module matching area can provide a flat contact surface, so that the second light emitting module 20 is ensured to be stably attached to the first light emitting module 10, and the compact design not only saves space, but also is convenient to carry and store, and improves the portability of the lamp.

In the embodiment of the application, the man-machine interaction region 12 is positioned at one side or two sides of the length direction of the second light-emitting module matching region, and the layout optimizes the position of the man-machine interaction region 12, so that the man-machine interaction region is still easy to operate when the second light-emitting module 20 is folded, and the use experience of a user is improved. For example, the man-machine interaction area 12 is located at one side or two sides of the second light emitting module matching area, so that when the second light emitting module 20 is folded, a user can easily control the lighting parameters of the lamp by touching or operating the man-machine interaction area 12, thereby avoiding the man-machine interaction area 12 from being blocked by the second light emitting module 20 and ensuring that the user can conveniently operate the lamp in any state.

As in the examples of fig. 1 and 2, the second light emitting module mating region of the first light emitting module 10 is located on the front surface of the first light emitting module 10, and the man-machine interaction regions 12 are disposed on both sides of the second light emitting module mating region. Of course, in some embodiments not shown, the human-computer interaction area may also be disposed on other surfaces of the first light emitting module, such as the upper surface, the left surface, the right surface, and so on.

More specifically, as can be seen from the above description, the man-machine interaction area in the embodiment of the present application can control the illumination parameters of the first light emitting module 10 and the second light emitting module 20, and of course, can also control some other functions, such as a light sensing switch, a man-machine sensing switch, adjusting an illumination mode, collecting a current illumination mode, etc., under some specific scene requirements.

The structure of the first light emitting module 10 and the structure of the second light emitting module 20 are specifically described as follows:

Specifically, as shown in fig. 15 and 16, the first light emitting module 10 includes:

The first light emitting surface 101 with a first light emitting opening is formed on the surface of the first lamp housing 1a, and a first light source 1b, a reflecting piece 1c and a first light emitting cover 1d are arranged in the first lamp housing 1 a;

The first light-emitting cover 1d is disposed corresponding to the first light-emitting opening, the first light source 1b is disposed at a position deviated from the first light-emitting opening, and the light beam emitted by the first light source 1b can be emitted from the first light-emitting opening through the reflection of the reflecting member 1 c.

It should be noted that, in the embodiment of the present application, the term "offset" is used to describe a relative positional relationship between the first light source 1b and the first light outlet. Specifically, "offset" means that the first light source 1b is disposed at a position inside the first lamp housing 1a, and the projection of the first light source 1b on the plane where the first light outlet is located is not overlapped with the first light outlet. So that at least part of the light beam emitted by the first light source 1b is not directly emitted from the first light outlet, but is emitted from the first light outlet after being reflected by the reflecting member 1 c. This arrangement ensures that the light beam can pass through the reflector 1c, thereby achieving a specific light-emitting effect.

Preferably, the reflecting member 1c has a flat reflecting surface obliquely disposed in the first lamp housing. The reflecting member 1c can reflect the light of the first light source 1b to be emitted from the first light outlet.

Further preferably, the first light emitting module 10 further includes a main control board 1e and a switching circuit board 1f, wherein a control element and/or a communication element and/or a power supply element are integrated on the main control board 1e, and a man-machine interaction element and/or an audio/video acquisition element and/or a sensor element are integrated on the switching circuit board 1 f. Preferably, the interaction element, the camera, the hall sensor, the radar, the microphone, the hall sensor and other elements are all loaded on the forward-facing switching circuit board 1f in the lamp pole, and the main control board 1e in the lamp pole is mainly responsible for communication, power supply and control of each component, for example, the elements on the main control board 1e can comprise an LED driving element of the first light emitting module, an OVP protection circuit, an LED driving element of the second light emitting module, an LDO, an MCU, a WIFI module and the like. It should be noted that, in the lamp provided in this embodiment, the main control board and the switching circuit board are specifically designed due to too many components.

In the embodiment of the application, the first light source 1b, the reflecting member 1c and the first light-emitting cover 1d are arranged in the first light-emitting module 10, and the design ensures that the light emitted by the first light source 1b can be efficiently reflected by the reflecting member 1c and uniformly distributed by the first light-emitting cover 1 d. For example, the straight reflecting surface of the reflecting member 1c can efficiently reflect the light emitted by the first light source 1b, ensure that the light is uniformly emitted from the first light outlet, and the first light outlet cover 1d can further diffuse the light, so that the light can be uniformly irradiated to the target area, and the lighting effect is improved. While the reflecting member 1c has a flat reflecting surface obliquely disposed in the first lamp housing, this design optimizes the reflecting path of the light rays, ensuring that the light rays can be efficiently emitted from the first light outlet. For example, the inclined straight reflecting surface can reflect light to the first light outlet, so that the light loss is reduced, the lighting efficiency is improved, and meanwhile, the reflecting surface of the reflecting piece 1c is a straight surface instead of a curved surface, so that the lighting quality of the first light emitting module 10 is improved, the occupied space of the reflecting piece 1c is reduced, and the structure of the lamp is more compact. In other embodiments, the reflecting member 1c may be curved.

The first light-emitting mask 1d of the first light-emitting module 10 may be a transparent light-emitting plate or an etched plate.

In more detail, as shown in fig. 17 and 18, the second light emitting module 20 includes:

A second light emitting surface 201 with a second light emitting opening is formed on the surface of the second lamp housing 2a, and a light guide plate 2b and a second light source 2c are arranged in the second lamp housing 2 a;

Wherein the light guide plate 2b is disposed corresponding to the second light outlet, and the second light source 2c is disposed at a position deviated from the second light outlet and corresponding to the side plate of the light guide plate 2 b.

Preferably, the second light emitting port of the second light emitting module 20 is further provided with a soft light plate and a diffusion plate.

Further preferably, the second lamp housing 2a includes a bottom shell 2a1 and a surface shell 2a2 which are in butt-fit, wherein a second light emitting surface 201 with a second light emitting opening is formed on the surface shell 2a 2.

In the embodiment of the application, the second light emitting module 20 is internally provided with the light guide plate 2b and the second light source 2c, and the light guide plate 2b is correspondingly arranged with the second light outlet, so that the design ensures that the light rays emitted by the second light source 2c can be efficiently transmitted to the second light outlet through the light guide plate 2b and are uniformly distributed. For example, the light guide plate 2b can uniformly diffuse the light of the point light source or the linear light source to the whole second light outlet area to provide a uniform illumination effect, and the design not only improves the illumination efficiency of the second light emitting module 20, but also ensures the uniform distribution of the light, and avoids the problem of local over-brightness or over-darkness.

The position of the second light outlet in the embodiment of the application can make the light of the second light emitting module 20 softer, reduce glare and shadow and improve the illumination comfort by arranging the soft light plate and the diffusion plate. For example, the soft light plate and the diffusion plate can further diffuse light, so that the light is more uniform and softer, and the light is suitable for scenes requiring soft light such as facial light filling, and the design not only improves the illumination quality of the second light-emitting module 20, but also enhances the use experience of users.

In the embodiment of the application, the second lamp housing 2a comprises the bottom shell 2a1 and the surface shell 2a2 which are in butt joint and matched relatively, and the surface shell 2a2 is provided with the second light emitting surface 201 with the second light emitting opening, so that the structure of the second light emitting module 20 is more compact, the space occupation is reduced, and meanwhile, the assembly and the maintenance are convenient. For example, the butt-joint matching design of the bottom shell 2a1 and the surface shell 2a2 enables the internal components of the second light-emitting module 20 to be compactly installed inside, so that the overall stability of the lamp is improved, and the design not only simplifies the manufacturing process, but also reduces the production cost, and simultaneously maintains the overall aesthetic property of the lamp.

Further, in some possible embodiments, the light guide plate 2B includes a light guide plate surface a facing the second light outlet, and a light guide plate surface B facing away from the second light outlet and facing the second lamp housing wall;

The second light emitting module 20 further includes a second light emitting cover 2d, a reflective paper 2e and foam 2f, wherein the second light emitting cover 2d is pressed in a gap between the light guiding plate surface a and the second light emitting opening, the reflective paper 2e is attached to the light guiding plate surface B of the light guiding plate 2B, and the foam 2f is pressed in a gap between the reflective paper 2e and the lamp housing of the second light emitting module 20.

In the embodiment of the application, the second light-emitting cover 2d is pressed in the gap between the light guide plate surface A and the second light-emitting opening, and the design ensures that the light emitted by the light guide plate 2b can be efficiently transmitted to the second light-emitting opening and uniformly distributed through the second light-emitting cover 2 d. For example, the second light-emitting cover 2d can further diffuse and homogenize the light, so as to ensure that the light of the second light-emitting module 20 irradiates the target area more uniformly, and the design not only improves the illumination efficiency of the second light-emitting module 20, but also ensures the uniform distribution of the light, and avoids the problem of local over-brightness or over-darkness. The reflective paper 2e is attached to the light guide plate surface B of the light guide plate 2B, and the reflective paper 2e reflects the light on the back surface of the light guide plate 2B back to the light guide plate surface a, so that the light utilization efficiency is improved. For example, the reflective paper 2e can reflect the light on the back of the light guide plate 2b back to the light guide plate surface a, so as to reduce the loss of the light and improve the illumination efficiency, and the design not only improves the brightness of the second light emitting module 20, but also ensures the uniform distribution of the light and improves the illumination quality. The foam 2f is pressed in the gap between the reflective paper 2e and the lamp housing of the second light emitting module 20, and this design provides good sealing and buffering effects through the foam 2f, so as to ensure the internal structure of the second light emitting module 20 to be stable. For example, the foam 2f can absorb vibration, reduce the influence of mechanical impact on internal components, improve the service life of the lamp, simultaneously the foam 2f can provide good sealing performance, prevent dust and impurities from entering the second light-emitting module 20, keep the cleanness and performance of the internal components, and in addition, the foam can enable all parts of the whole machine to be attached in place, then the bottom shell is pressed on the pre-pressed foam, and finally the pre-pressed foam is firmly fixed with the face shell through the buckling position.

In detail, referring to fig. 18, the second light emitting module 20 in the embodiment of the present application is assembled by the second light emitting cover 2d and the surface shell 2a2 through the positioning hole, the second light source 2c on the side surface is glued on the rib of the side wall of the surface shell 2a2 through double-sided gluing, the light guiding plate 2b is placed above the second light emitting cover 2d, so as to ensure that the light guiding plate 2b and the second light source 2c are centered and correspond to each other, i.e. the center of the lamp bead of the second light source 2c corresponds to the center line of the light guiding plate 2b, the best light transmission effect is achieved, the upper part of the light guiding plate 2b is isolated through the reflective paper 2e, so as to ensure that the light source faces the second light emitting opening of the second light emitting surface 201 uniformly, and simultaneously, the pre-pressed foam 2f is placed above the reflective paper 2e, so that all the components of the whole machine are attached in place, and then the light guiding plate 2a1 is pressed on the pre-pressed foam 2f, and the pre-pressed foam 2f is fixed firmly with the surface shell 2a2 through the fastening position.

More specifically, as shown in fig. 1 to 12, the first light emitting module 10 is configured as a strip-shaped lamp body, and the second light emitting module 20 is configured as a sheet-shaped lamp body;

the first light emitting module 10 has a front surface facing the user side, a rear surface facing away from the user side, and upper and lower surfaces interposed between the front and rear surfaces, the lower surface side forming a first light emitting surface 101 having a first light emitting opening;

The rotational connection position of the second light emitting module 20 and the first light emitting module 10 is located at the engagement position between the front surface and the upper surface;

After the second light emitting module 20 is folded relative to the first light emitting module 10, the second light emitting surface 201 of the second light emitting module 20 faces and is close to the front surface of the first light emitting module 10, when the second light emitting module 20 is unfolded relative to the first light emitting module 10 and is used for facial light supplement, the second light emitting surface 201 of the second light emitting module 20 is located above the upper surface of the first light emitting module 10, and the second light emitting surface 201 of the second light emitting module 20 faces to one side of the user.

In an embodiment, which is not shown, the rotational connection position of the second light emitting module 20 and the first light emitting module 10 is located on the upper surface of the first light emitting module 10, after the second light emitting module 20 is folded relative to the first light emitting module 10, the second light emitting surface 201 of the second light emitting module 20 faces and is close to the upper surface of the first light emitting module 10, when the second light emitting module 20 is unfolded relative to the first light emitting module 10 and is used for facial light supplement, the second light emitting surface 201 of the second light emitting module 20 is located above the upper surface of the first light emitting module 10, and the second light emitting surface 201 of the second light emitting module 20 faces to the user side.

In another embodiment, not shown, the rotational connection position of the second light emitting module 20 and the first light emitting module 10 is located at the connection position of the upper surface and the front surface of the first light emitting module 10, after the second light emitting module 20 is folded relative to the first light emitting module 10, the second light emitting module 20 is attached to the upper surface of the first light emitting module 10 with the second light emitting surface 201 facing upwards, and when the second light emitting module 20 is unfolded relative to the first light emitting module 10 and is used for facial light supplement, the second light emitting surface 201 of the second light emitting module 20 is located above the first light emitting module 10, and the second light emitting surface 201 of the second light emitting module 20 faces towards the user side.

In another embodiment, not shown, the rotational connection position of the second light emitting module 20 and the first light emitting module 10 is located at the connection position between the upper surface and the front surface of the first light emitting module 10, after the second light emitting module 20 is folded relative to the first light emitting module 10, the second light emitting surface 201 of the second light emitting module 20 faces and is close to the upper surface of the first light emitting module 10, when the second light emitting module 20 is unfolded relative to the first light emitting module 10 and is used for facial light supplement, the second light emitting surface 201 of the second light emitting module 20 is located in front of the front surface of the first light emitting module 10, and the second light emitting surface 201 of the second light emitting module 20 faces to the user side.

Preferably, the front surface of the first light emitting module 10 is provided with an audio/video collecting area and a man-machine interaction area, wherein the audio/video collecting area is covered by the second light emitting module 20 after the second light emitting module 20 is folded, and the man-machine interaction area 12 is not covered by the second light emitting module 20 after the second light emitting module 20 is folded.

Further preferably, the length of the second light emitting module 20 is smaller than the length of the first light emitting module 10, and the second light emitting module 20 is disposed at a middle position of the first light emitting module 10 in the length direction.

In the embodiment of the application, after the second light emitting module 20 is folded relative to the first light emitting module 10, the second light emitting surface 201 faces towards and is closely attached to the front surface of the first light emitting module 10, so that the second light emitting module 20 can be close to the first light emitting module 10 when folded, the space occupation is reduced, and the whole lamp is more compact. For example, when the second light emitting module 20 is not used, the second light emitting module 20 is folded and then is closely attached to the first light emitting module 10, so that space is saved, portability and storage are facilitated, and when the second light emitting module 20 is fully unfolded, the second light emitting surface 201 is located above the upper surface of the first light emitting module 10 and faces to one side of a user, and the design enables the second light emitting module 20 to provide an optimal light supplementing effect when being unfolded, and meanwhile, mutual interference with light rays of the first light emitting module 10 is avoided. For example, the second light emitting surface 201 of the second light emitting module 20 is located above the first light emitting module 10, so that the face of the user can be directly illuminated, and the arrangement is suitable for scenes such as video call and makeup, and the like, so that the lighting effect is optimized, and the first light emitting module 10 and the second light emitting module 20 can work independently and are not interfered with each other.

In the embodiment of the application, the front surface of the first light-emitting module 10 is provided with the audio and video acquisition area, and the audio and video acquisition area is shielded by the second light-emitting module 20 after the second light-emitting module 20 is folded, so that the design automatically shields the audio and video acquisition area when the second light-emitting module 20 is folded, thereby ensuring that the privacy of a user is protected. For example, when the user does not need to use the audio/video acquisition function, the second light-emitting module 20 is folded, the audio/video acquisition area is shielded, privacy leakage is avoided, the design obviously enhances the control of the user on the privacy, the safety and the reliability of the lamp are improved, the man-machine interaction area is not shielded by the second light-emitting module 20 after the second light-emitting module 20 is folded, the design ensures that the man-machine interaction area can be conveniently operated in any state, and the use experience of the user is improved. For example, when the second light emitting module 20 is folded or unfolded, the user can easily adjust the lighting parameters of the lamp through the human-computer interaction area, so that the human-computer interaction area is prevented from being blocked, and the user can conveniently operate the lamp in any state.

In the embodiment of the application, the length of the second light-emitting module 20 is preferably smaller than that of the first light-emitting module 10, and the second light-emitting module 20 is arranged at the middle position of the first light-emitting module 10 in the length direction, so that the design not only optimizes the structure of the lamp, but also balances the visual effect, and the whole lamp looks more coordinated. For example, the length of the second light emitting module 20 is smaller than that of the first light emitting module 10, so that the second light emitting module 20 is prevented from being too protruded when being unfolded to affect the overall attractive appearance, and the second light emitting module 20 is arranged in the middle of the first light emitting module 10, so that the lamp is more balanced in vision, and the overall attractive appearance is improved. Of course, in some alternative embodiments, the length of the second light emitting module 20 may also be set to be the same or substantially the same as the length of the first light emitting module 10.

Further, in some possible embodiments, the lamp further includes a rotating connection member 30, and the second light emitting module 20 is rotatably mounted on the first light emitting module 10 through the rotating connection member 30;

The rotary connection part 30 includes a rotary shaft support 31, a rotary shaft housing 32 and a rotary shaft body 33, the rotary shaft support 31 is fixed on the first light emitting module 10, and a shaft hole is formed on the rotary shaft support 31, the rotary shaft housing 32 is installed in the shaft hole of the rotary shaft support 31, a part of the rotary shaft body 33 is rotatably sleeved in the rotary shaft housing 32, another part of the rotary shaft body 33 is arranged outside the rotary shaft housing 32 and is fixed with a locking member 34, and the locking member 34 is used for fixing the second light emitting module 20 and the rotary shaft body 33 together.

Further, in some possible embodiments, a limiting structure is formed between the rotating shaft body 33 and the rotating shaft housing 32, and the limiting structure is used to limit the unfolding angle of the second light emitting module 10 relative to the first light emitting module 20.

Preferably, a positioning surface 331 is convexly disposed on at least a portion of the surface of the rotating shaft body 33 located outside the rotating shaft housing 32, and a stop block 321 disposed on a rotating path of the positioning surface 331 is disposed on the rotating shaft housing 32, wherein when the rotating shaft body 33 rotates forward and backward relative to the rotating shaft housing 32, opposite ends of the positioning surface 331 in the rotating direction can be in abutting engagement with two end surfaces of the stop block 321 in the circumferential direction, so as to limit a rotating angle of the second light emitting module 20 relative to the first light emitting module 10.

Further preferably, the limiting structure can limit the forward and backward rotation of the second light emitting module 10 relative to the first light emitting module to not more than 180 °. In some other embodiments, the limiting structure can limit the forward and backward rotation of the second light emitting module 10 relative to the first light emitting module by no more than 270 °.

The second light emitting module 20 in the embodiment of the present application is rotatably mounted on the first light emitting module 10 through the rotation connection part 30, and this design provides a stable rotation connection, ensuring that the second light emitting module 20 can flexibly rotate on the first light emitting module 10 while maintaining structural stability and reliability. For example, the combination design of the rotating shaft bracket 31, the rotating shaft housing 32 and the rotating shaft body 33 enables the second light-emitting module 20 to rotate more smoothly, and reduces mechanical friction and abrasion. The use of the locking member 34 ensures a firm connection between the second light emitting module 20 and the rotating shaft body 33, and improves the overall stability of the lamp. The limiting structure formed between the rotating shaft body 33 and the rotating shaft shell 32 realizes the accurate angle control of the second light-emitting module 20, and ensures that the second light-emitting module 20 can be kept within a proper unfolding angle range during use. For example, the limiting structure can limit the forward and backward rotation of the second light emitting module 20 relative to the first light emitting module 10 to not more than 180 degrees, so that structural damage caused by excessive rotation of the second light emitting module 20 is avoided.

Specifically, the positioning surface 331 is convexly arranged on at least part of the surface of the rotating shaft body 33, which is located outside the rotating shaft housing 32, and the positioning block 321, which is located on the rotating path of the positioning surface 331, is arranged on the rotating shaft housing 32, so that the internal structure of the rotating connecting component 30 is optimized, and the limiting function is more accurate and reliable. For example, the matching design of the positioning surface 331 and the stop block 321 ensures that the second light emitting module 20 can accurately reach the preset angle limit during rotation.

It can be seen that when the second light emitting module 20 and the first light emitting module 10 are rotationally connected together through the rotational connection part 30 having the above structure, stable rotational connection and precise angle control can be realized, and a user can flexibly adjust the angle of the second light emitting module 20 according to different usage scenarios, while enjoying stable lighting effects. For example, during a video call, the user can adjust the second light emitting module 20 to a proper angle to illuminate the face while the first light emitting module 10 continues to illuminate the desktop to provide soft background light, and during reading or writing, the user can fold the second light emitting module 20 to avoid light interference while the first light emitting module 10 provides uniform illumination.

Further, in some possible embodiments, the lamp further comprises a lamp base 40, and the first light emitting module 10 is connected to the lamp base 40 and is mounted at the target mounting position through the lamp base 40.

The lamp base 40 in the embodiment of the application is connected to the first lighting module 10, and the design provides stable support for the lamp, so that the lamp cannot shake or topple during use. For example, the lamp base 40 may be made of a strong material, such as metal or high strength plastic, to provide sufficient support, and the base design may include a cleat or other anti-slip means to further enhance stability. At the same time, the design that the lamp base 40 is connected to the first light emitting module 10 allows a user to select different mounting modes according to different use situations. For example, the lamp base 40 can be designed into a clamp form, so that the lamp can be clamped on a display screen of equipment to be clamped conveniently, and for example, the lamp base 40 can also be designed into a desktop placing base, so that the lamp is suitable for desktop illumination, and the design remarkably improves the use experience of a user. The user can select a proper installation mode according to own requirements, so that the lamp can be stably used in any scene.

It should be noted that the device to be clamped includes, but is not limited to, a computer, an ipad, a television, etc., and preferably, the lamp may be hung or clamped on a device screen of the device to be clamped when being installed with the device to be clamped.

Further, a bayonet 401 is further formed on the lamp base 40, and the lamp base 40 can be clamped on the body to be mounted through the bayonet 401.

In some possible embodiments, the luminaire base 40 includes a connection portion 40a and a weight portion 40b, one end of the connection portion 40a extending upward to connect the first light emitting module 10 away from the back face for one side, and the other end extending downward to connect the weight portion 40b. The weight of the counterweight 40b is designed such that the center of gravity extension of the lamp can pass through or approach the engagement surface of the body to be mounted when the lamp base 40 is engaged or engaged with the body to be mounted.

The lamp base 40 in the embodiment of the application comprises the connecting part 40a and the counterweight part 40b, and the weight design of the counterweight part 40b enables the gravity center extension line of the lamp to pass through or approach the clamping surface of the body to be installed, so that the design ensures the stability of the lamp when the lamp is hung or clamped on the body to be installed, and prevents the lamp from shaking or tilting. For example, the reasonable design of the weight 40b makes the gravity center of the lamp more stable, and the lamp can be balanced even on uneven surfaces, so that the design not only improves the use safety of the lamp, but also prolongs the service life of the lamp, and the bayonet 401 formed on the lamp base 40 can be clamped on a body to be mounted through the bayonet 401, so that a flexible mounting mode is provided, and a user can select a proper mounting position according to different use situations. For example, the bayonet 401 can be conveniently clamped on the surface of a computer display, a bookshelf or other objects, so that space is saved, and the adaptability of the lamp is improved and the use experience of a user is enhanced.

As described above, the lamp base in the embodiment of the application is used for being connected with the first lighting module 10 and can be hung on a display screen, that is, the lamp base at this time is used as a screen hanging lamp base, but in some embodiments not shown, the lamp base may also be used as a desk lamp base.

Further, a second aspect of the present application provides an electronic device, including a first light emitting module 10 for providing illumination to a table surface and a second light emitting module 20 for supplementing light to a face of a user, where the second light emitting module 20 is movably connected with respect to the first light emitting module 10;

The electronic device further comprises a collecting module 11 located on the outer surface of the first light emitting module 10 or the light emitting surface of the second light emitting module 20, wherein the collecting module 11 can be exposed or shielded when the second light emitting module 20 is located at different active positions, and the collecting module 11 comprises at least one of an audio collecting module and a video collecting module.

Preferably, the first light emitting module 10 and the second light emitting module 20 are movably connected together by adopting a rotational connection manner in the example of fig. 1, however, in some embodiments not shown, the first light emitting module 10 and the second light emitting module 20 may also be movably connected together by adopting a sliding connection manner or other movable connection manners, which only needs to ensure that the second light emitting module 20 can be exposed or shielded when being located at different movable positions.

As can be seen from the above description, in the embodiment of the application, the first light emitting module 10 is used for providing illumination for the table surface, and the second light emitting module 20 is used for supplementing light for the face of the user. This design allows the luminaire to provide not only the conventional lighting function of the first light emitting module 10, but also an additional light supplementing function through the second light emitting module 20. For example, when the user is talking, making up or doing fine work, the second light emitting module 20 can provide soft and uniform light for the face of the user, so as to improve the illumination quality, and when the light supplement is not needed, the second light emitting module 20 can be folded or adjusted to a position which does not affect the illumination of the first light emitting module 10. The collection module 11 is located on the outer surface of the first light emitting module 10 or the light emitting surface of the second light emitting module 20, and the second light emitting module 20 is located at different active positions to expose or shield the design of the collection module 11, so that the collection module 11 can be shielded when not needed to be used, privacy is protected, and meanwhile, the collection module can be exposed when needed to be used, and normal functions are ensured. For example, when the user does not need to use the audio or video capturing function, the second light emitting module 20 can be adjusted to cover the position of the capturing module 11, so that privacy leakage is avoided, and when video call or recording is needed, the second light emitting module 20 can be adjusted to expose the position of the capturing module 11, so that the capturing effect of audio and video is ensured.

In summary, the flexible design of the movable connection of the second light emitting module 20 and the flexible control of the acquisition module 11 significantly improves the user experience. The user can flexibly adjust the position of the second light emitting module 20 according to different usage scenarios, and enjoy the functions of the stable illumination and collection module 11 provided by the first light emitting module 10. For example, during a video call, the user can adjust the second light emitting module 20 to a proper angle to illuminate the face, while the acquisition module 11 provides high definition video and clear audio, and during reading or writing, the user can fold the second light emitting module 20 to avoid light interference, while the first light emitting module 10 provides uniform illumination.

In the foregoing embodiments of the present application, the descriptions of the embodiments are emphasized, and for a portion of this disclosure that is not described in detail in this embodiment, reference is made to the related descriptions of other embodiments. The steps illustrated in the associated flow diagrams may be performed in a computer system, such as a set of computer-executable instructions, and, although a logical order is illustrated in the flow diagrams, in some cases, the steps illustrated or described may be performed in a different order than that illustrated herein. In other words, the order of steps described in the foregoing embodiments is merely an example, and it is within the scope of the embodiments of the present application to reasonably adjust the order of steps based on the content of the embodiments of the present application.

The serial numbers or the introduced sequences of the embodiments of the present application are only for description, and do not represent the advantages and disadvantages of the embodiments.

In the description of the present specification, a description referring to terms "one embodiment," "some embodiments," "examples," "specific examples," or "some examples," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present invention. In this specification, schematic representations of the above terms are not necessarily directed to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Further, one skilled in the art can engage and combine the different embodiments or examples described in this specification.

While embodiments of the present invention have been shown and described above, it will be understood that the above embodiments are illustrative and not to be construed as limiting the invention, and that variations, modifications, alternatives and variations may be made to the above embodiments by one of ordinary skill in the art within the scope of the invention.

Claims (19)

1. A light fixture, comprising:

The LED lamp comprises a first light-emitting module (10) and a second light-emitting module (20), wherein the second light-emitting module (20) is rotationally connected with the first light-emitting module (10), and the rotation axis L2 of the second light-emitting module (20) is parallel to the extension direction of the first light-emitting module (10);

The second light-emitting module (20) at least comprises a first position state and a second position state when rotating relative to the first light-emitting module (10), wherein the second light-emitting module (20) is used for supplementing light to the face of a user when being in the first position state and is close to the outer surface of the first light-emitting module (10) when being in the second position state;

When the second light-emitting module (20) is used for supplementing light to the face of a user, the optical axis direction of the second light-emitting module (20) is not parallel to the optical axis direction of the first light-emitting module (10).

2. A luminaire as claimed in claim 1, characterized in that the first light emitting module (10) has a first light exit surface (101) and the second light emitting module (20) has a second light exit surface (201);

the first light emitting surface (101) is arranged at the bottom of the first light emitting module (10);

the second light emitting surface (201) can change the direction along with the rotation of the second light emitting module (20);

the second light emitting surface (201) is shielded when the second light emitting module (20) is located in the second position state.

3. A light fixture as recited in claim 2, wherein,

When the second light emitting module (20) is in the second position state, the second light emitting surface (201) is hidden between the first light emitting module (10) and the second light emitting module (20), or the second light emitting surface (201) is hidden in the first light emitting module (10).

4. A luminaire as claimed in claim 1, characterized in that the first light emitting module (10) comprises:

The LED lamp comprises a first lamp housing (1 a), wherein a first light emitting surface (101) with a first light emitting opening is formed on the surface of the first lamp housing (10), and a first light source (1 b), a reflecting piece (1 c) and a first light emitting cover (1 d) are arranged in the first lamp housing (1 a);

The first light outlet cover (1 d) is arranged corresponding to the first light outlet, the first light source (1 b) is arranged at a position deviating from the first light outlet, and light beams emitted by the first light source (1 b) can be emitted from the first light outlet through reflection of the reflecting piece (1 c).

5. A luminaire as claimed in claim 4, characterized in that the reflector (1 c) has a flat reflecting surface arranged obliquely in the first lamp housing.

6. The luminaire according to claim 1, wherein the second light emitting module (20) comprises:

A second light emitting surface (201) with a second light emitting opening is formed on the surface of the second light housing (2 a), and a light guide plate (2 b) and a second light source (2 c) are arranged in the second light housing (2 a);

the light guide plate (2 b) is arranged corresponding to the second light outlet, and the second light source (2 c) is arranged at a position deviating from the second light outlet and corresponds to a side plate surface of the light guide plate (2 b).

7. A luminaire as claimed in claim 6, characterized in that the second light outlet position of the second light emitting module (20) is further provided with a diffuser plate and/or a diffuser plate.

8. The luminaire of claim 1, wherein the second light emitting module (20) is automatically turned on when the second light emitting module (20) is turned on to a first preset angle, and wherein the second light emitting module (20) is automatically turned off when the second light emitting module (20) is turned off to a second preset angle.

9. The luminaire of claim 8, further comprising a position sensing module for use with the first light emitting module (10) and the second light emitting module (20), the position sensing module being configured to detect a rotation angle of the second light emitting module (20) relative to the first light emitting module (10).

10. The lamp as claimed in claim 9, wherein the position sensing module comprises a hall sensor and a magnet, wherein one of the first light emitting module (10) and the second light emitting module (20) is provided with the hall sensor, the other one is provided with the magnet, the hall sensor can sense the magnetic force of the magnet when the second light emitting module (20) rotates relative to the first light emitting module (10), and the second light emitting module (20) is controlled to be turned on or off according to the sensed magnetic force.

11. A luminaire as claimed in claim 1, characterized in that the second light emitting module (20) and/or the first light emitting module (10) are provided with a video acquisition module;

The video acquisition module is shielded when the second light emitting module (20) is in the second position state.

12. The luminaire as claimed in claim 1, characterized in that the outer surface of the first light emitting module (10) is further provided with a human-machine interaction area (12), the human-machine interaction area (12) being adapted to recognize external instructions and to control the first light emitting module (10) and/or the second light emitting module (20).

13. A luminaire as claimed in claim 12, characterized in that the outer surface of the first light emitting module (10) has a second light emitting module mating area corresponding to the position of the second light emitting module (20) when the second light emitting module (20) is in the second position state;

The man-machine interaction area (12) is located at a position of the first light-emitting module (10) except for the second light-emitting module matching area.

14. A luminaire as claimed in claim 1, characterized in that the first light-emitting module (10) is configured as an elongated lamp body and the second light-emitting module (20) is configured as a sheeted lamp body;

the lower surface of the first light-emitting module (10) forms a first light-emitting surface (101) with a first light-emitting opening;

The rotary connection position of the second light-emitting module (20) and the first light-emitting module (10) is positioned at the connection position between the front surface and the upper surface of the first light-emitting module (10);

the second light emitting module (20) is positioned close to the front surface of the first light emitting module (10) when being positioned in the second position state.

15. The lamp as claimed in claim 14, wherein the second light emitting module (20) has a length smaller than that of the first light emitting module (10), and the second light emitting module (20) is disposed at a middle position in a length direction of the first light emitting module (10).

16. A luminaire as claimed in any one of claims 1-15, characterized in that the luminaire further comprises a rotational connection member (30), the second light emitting module (20) being rotatably mounted on the first light emitting module (10) by means of the rotational connection member (30);

The rotating connecting component (30) comprises a rotating shaft support (31), a rotating shaft shell (32) and a rotating shaft body (33), wherein the rotating shaft support (31) is fixed on the first light-emitting module (10), a shaft hole is formed in the rotating shaft support (31), the rotating shaft shell (32) is installed in the shaft hole of the rotating shaft support (31), one part of the rotating shaft body (33) is sleeved in the rotating shaft shell (32) in a rotating mode, the other part of the rotating shaft body is arranged outside the rotating shaft shell (32) and is fixedly provided with a locking piece (34), and the locking piece (34) is used for fixing the second light-emitting module (20) and the rotating shaft body (33) together.

17. The lamp as claimed in claim 16, characterized in that a limiting structure is formed between the rotating shaft body (33) and the rotating shaft housing (32), the limiting structure being used for limiting the unfolding angle of the second light emitting module (10) relative to the first light emitting module (20).

18. A luminaire as claimed in claim 1, characterized in that the luminaire further comprises a luminaire mount (40), the first light emitting module (10) being connected to the luminaire mount (40) and being mounted in a target mounting position by the luminaire mount (40).

19. An electronic device, characterized by comprising a first light emitting module (10) for providing illumination to a table top and a second light emitting module (20) for supplementing light to the face of a user, wherein the second light emitting module (20) is movably connected relative to the first light emitting module (10);

The electronic equipment further comprises a collecting module (11) located on the outer surface of the first light-emitting module (10) or the light-emitting surface of the second light-emitting module (20), wherein the collecting module (11) can be exposed or shielded when the second light-emitting module (20) is located at different active positions, and the collecting module (11) comprises at least one of an audio collecting module and a video collecting module.