KR20180121233A - Smart lighting device - Google Patents

Abstract

According to an embodiment of the present invention, provided is a smart lighting device which can recognize tilting of a lighting according to a direction in which a light is irradiated to automatically adjust an irradiation angle of the light, and can be used as a stand when the smart lighting device is mounted on a cradle as well as being portable. The smart lighting device comprises: a main body unit; a first lighting module received in the main body unit, and irradiating light in a first direction; a lens module installed at a front end of the first lighting module to adjust an irradiation angle of the light; a first sensor module installed in the main body unit, and sensing a tilting degree that the first direction is tilted from a horizontal direction; and a zoom adjusting module for moving the lens module back and forth along the first direction according to an inclination value of the first direction sensed by the first sensor module to adjust the irradiation angle of the light irradiated by the first lighting module.

Description

[0001] Smart lighting device [0002]

The present invention relates to a smart illumination device, and more particularly, to a smart illumination device which recognizes a tilting of an illumination according to a direction of illumination and automatically adjusts an irradiation angle of light, ≪ / RTI >

As the desire to get away from tired everyday life and to live with nature increases, more and more people want to enjoy outdoor leisure activities such as camping and hiking. Particularly, people who enjoy outdoor activities actively in the night as well as in the daytime, and various lighting devices necessary for outdoor activities at night are required.

Portable lanterns are usually used for outdoor activities at night. The lantern has a built-in battery so that the separate power line is not exposed and can be used independently. The lantern uses a bulb or an LED element as a light emitter, and has a structure that collects light in a specific direction or irradiates the light uniformly in all directions. Most lanterns have a way of collecting light in specific directions for light efficiency.

At this time, the irradiation angle may be different depending on the use of the lantern. For example, a lantern for illuminating distant places is effective because the angle of irradiation is narrow, and the lantern for illuminating a nearby place has a broad range of viewing angle. As described above, although the irradiation angle of the light irradiated by the lantern differs depending on the application, most of the lanterns have a manual inconvenience that the irradiation angle of the light is fixed or the irradiation angle is adjusted manually.

In addition, when the outdoor lantern is used indoors, it is inconvenient to adjust the light irradiation direction or to mount the lantern.

Korean Patent No. 10-1580245 (Dec. 18, 2015)

An object of the present invention is to provide a smart lighting device capable of automatically recognizing an inclination of an illumination according to a lighting direction and automatically adjusting an angle of light irradiation and being used as a portable and also used as a stand when mounted on a cradle .

The technical objects of the present invention are not limited to the technical matters mentioned above, and other technical subjects not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided a smart illumination device including a main body, a first illumination module housed in the main body and configured to irradiate light in a first direction, A first sensor module installed in the main body and sensing a degree of inclination of the first direction from a horizontal direction, and a second sensor module installed in the main body to detect an inclination of the first direction from a horizontal direction, And a zoom adjusting module for adjusting the irradiation angle of the light irradiated by the first illumination module by moving the lens module back and forth along the first direction according to the tilt value of one direction.

Wherein the zoom module adjusts an irradiation angle of light radiated by the first illumination module by moving the lens module when the inclination value of the first direction gradually increases downward, The irradiation angle of the light irradiated by the first illumination module can be gradually reduced if the first direction is in the horizontal direction.

Wherein the lens module includes a convex lens, and when the tilt value of the first direction is gradually increased downward, the zoom module approximates the lens module to the first illumination module, and the tilt value in the first direction is gradually smaller So that the lens module can be adjusted away from the first illumination module when the first direction approaches the horizontal direction.

The zoom adjusting module may further include a screw bar extending in the first direction, a driving part for driving the screw bar to rotate, and a screw thread engaging the screw bar on an inner circumferential surface through which the screw bar passes, And a moving block that moves and is fixed to the lens module.

And a second sensor module installed in the main body unit and recognizing the position of the lens module including the magnet part and the position sensor, wherein the magnet part is installed in one of the lens module or the main body part, The sensor is installed on the other one of the magnet part and the position sensor, and the position sensor recognizes the magnetic field of the magnet part and can recognize the position of the lens module.

The zoom module may move the lens module to a position where the magnet unit and the position sensor overlap when the first illumination module is powered off.

And a second illumination module installed in the main body part. The light emitted from the second illumination module may be radiated in a second direction different from the first direction and irradiated outside the main body part.

The main body may be provided with a light irradiation window of a transparent or semi-transparent material on a side portion thereof, and the second illumination module may be installed inside the light projection window.

Wherein the first illumination module is deactivated and only the second illumination module is activated when the body portion is mounted on the cradle.

The cradle may include a stand on which a floor is supported, and a rotation module to which the body portion is fixed and is rotatably coupled to the stand.

The rotating module may include a rotating plate having a rotation axis formed in a horizontal direction and having a center hole at a center thereof, and a rotating plate fixed to the bottom of the stationary hole and rotated in a horizontal direction.

The smart illumination device according to the present invention can be used indoors or outdoors, and has a high utilization efficiency because it can change the irradiation angle of light according to a change in the illuminating direction and effectively illuminate any place close to a distant place.

In addition, when the illumination unit is mounted on the cradle, the direction of light is changed, and color, brightness, and irradiation position can be easily adjusted. Especially, it can be controlled by various smart devices which are wireless communication devices, so that it is possible to easily control the lighting remotely according to the usage environment.

1 is a perspective view illustrating an illumination unit of a smart lighting device according to an embodiment of the present invention.
FIG. 2 is a side view showing the interior of the main body portion of FIG. 1 cut away. FIG.
3 is an exploded perspective view showing the first lighting module and the heat sink of FIG.
FIG. 4 is a view showing a state in which the irradiation angle of light changes according to the degree of tilting of the illumination unit of FIG. 1;
5 is a perspective view illustrating a cradle of a smart lighting device according to an embodiment of the present invention.
Fig. 6 is a cross-sectional view of the cradle of Fig. 5 cut longitudinally. Fig.
Fig. 7 is an operation diagram showing an operational view of the cradle of Fig. 5;
8 is a view showing an operation of a smart lighting device according to an embodiment of the present invention.
9 is a view showing a screen of a smart device controlling a smart lighting device according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention and the manner of achieving them will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. To fully disclose the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

In this specification, the terms 'shear' and 'rear end' may be distinguished based on the direction in which the light is irradiated. 'Shear' refers to the front part of the direction in which the light is emitted, and 'rear part' refers to the back part of the direction in which the light advances. For example, the light emitting side or the light emitting side or the connected portion thereof may be expressed by the front end of the apparatus, the constituent unit, or the like, and the opposite end of the front end may be expressed as the rear end. That is to say, those arranged or connected at the front end means disposed or connected to the light emitting side, and those disposed at the rear end or connected are disposed or connected to the opposite side of the light emitting portion.

Hereinafter, a smart illumination device according to an embodiment of the present invention will be described in detail with reference to Figs. 1 to 9. Fig.

The smart lighting device 1 according to an embodiment of the present invention is an illuminating device that can be used alone or in a cradle 20 and can be controlled by various smart devices in various ways. In particular, the illuminating unit 10 can be used alone as a lantern in the outdoors, and the irradiation angle of light is automatically adjusted according to the direction of light irradiation, which is very convenient. In addition, when the lighting unit 10 is mounted on the cradle 20, it can be used as a stand-type lighting that irradiates light to the side, and the color, brightness, and irradiation direction of light can be adjusted through a smart device, It can be used in various environments.

Hereinafter, the illumination unit 10 of the smart illumination apparatus 1 will be described in detail with reference to Figs. 1 to 4. Fig.

FIG. 1 is a perspective view showing an illumination part of a smart lighting device according to an embodiment of the present invention, FIG. 2 is a side view showing a part of the main part of FIG. FIG. 4 is a view showing a state in which the irradiation angle of light changes according to the degree of tilting of the illumination unit of FIG. 1. FIG.

Referring to FIGS. 1 and 2, the lighting unit 10 includes a main body 100 and a portable lighting module 100 housed in the main body 100 and adapted to illuminate light in a first direction A lens module 300 installed at a front end of the first illumination module 200 to adjust an irradiation angle of light and a second lens module 300 installed in the main body 100 and having a first direction inclined from a horizontal direction, A first sensor module 400 for detecting the degree of inclination of the lens module 300 according to a tilt value of the first direction detected by the first sensor module 400, And a zoom adjusting module 500 for adjusting the irradiation angle of the light irradiated by the light source 200.

The main body 100 is formed in a tubular shape and includes a first illumination module 200, a second illumination module 250, a lens module 300, a zoom adjustment module 500, a control module 600, Lt; / RTI >

The first illumination module 200 is accommodated in the main body 100 and irradiates light in a first direction (see A in FIG. 2) in the longitudinal direction of the main body 100. The first lighting module 200 is disposed at the front end of the main body 100 and is installed in the center of the heat sink 210. The heat dissipating plate 210 is used for rapidly discharging heat generated in the first lighting module 200 to the outside. The heat dissipating plate 210 discharges heat in contact with the main body 100. The first illumination module 200 includes an optical element 201 and an element substrate 202.

The heat dissipating plate 210 has a plurality of moving holes 211 arranged radially and communicates with the inside and the outside of the main body 100 through the moving holes 211. The moving hole 211 may serve as a passage through which the connection portion 304 of the lens module 300 moves and may also serve to increase the heat radiating area for dissipating the heat of the heat sink 210.

3, the central portion of the heat sink 210 on which the first lighting module 200 is seated is inwardly recessed to prevent the lens module 300 from being in direct contact with the optical element 201 even if the lens module 300 moves backward. can do.

The second illumination module 250 may be installed inside the main body 100 by irradiating light in a second direction different from the first direction (see B in FIG. 2). The second illumination module 250 may irradiate light to the side of the main body 100 and is attached to the side of the main body 100 and is disposed inside the main body 100 as shown in FIG. Light can be irradiated to the outside through the window 110 of semi-transparent material. The second illumination module 250 may be arranged to direct the light in the second direction and may direct light in another direction (e.g., the first direction) within the body 100 as shown in FIG. And the light may be irradiated in the second direction in the form of indirect light through the internal reflection and the diffusion function of the optical window 110.

The second illumination module 250 can emit a gentle light by irradiating light in indirect light form through the light-guiding window 110, and can be used as a reading light or the like, or can be used as a mood by appropriately adjusting the brightness of light.

Meanwhile, the second illumination module 250 may be formed of RGB LED (Red-Green-Blue Light Emitting Diode), and may emit light of various colors.

The second illumination module 250 may be inactivated and not operate when the lighting unit 10 used as a portable unit operates independently and may be activated only when the main unit 100 is mounted on the cradle 20 to be described later Can be controlled. That is, the second illumination module 250 is used to illuminate when the illumination unit 10 is mounted on the cradle 20 and used as a stand, rather than being used to directly illuminate the illumination unit 10 when the illumination unit 10 is used for portable purposes Can be used.

The lens module 300 is disposed at the front end of the first illumination module 200. The lens module 300 is disposed at the front end of the first illumination module 200 to adjust the irradiation angle of the light emitted from the first illumination module 200. Here, the 'irradiation angle of light' refers to an angle at which light irradiated in the form of a beam is spread, and corresponds to an angle of a bus line indicating a boundary of light in a light irradiated in a conical form with a light source as a vertex do.

That is, the lens module 300 adjusts the light irradiation range to be narrow or wide as the first and second illumination modules 200 are moved closer to or away from each other. The lens module 300 includes a lens 301 in front of the first illumination module 200, and the lens 301 may be a convex lens having a constant focal length. For example, when the lens 301 is a convex lens, as the optical element 201 approaches the focal distance of the lens 301, the light irradiation angle gradually increases. On the other hand, when the optical element 201 is gradually moved within the focal distance of the lens 301 and approaches the focal point of the lens 301, the irradiation angle of the light gradually becomes smaller and becomes close to the substantially parallel light beam of the cylindrical shape.

The smart illumination device 1 according to the embodiment of the present invention is not limited to the structure in which the lens 301 is moved in a state where the optical element 201 is fixed, The element 201 may approach or move away from the lens 301 and adjust the irradiation angle of the light.

The cover 120 may be coupled to the front end of the main body 100. The cover 120 is formed so as to surround the lens module 300 and to have a larger inner diameter as it gets further away from the body 100. That is, the angle formed by the cover 120 and the horizontal direction of the main body 100 is the same as when the angle of the light emitted from the first illumination module 200 is maximum, The light irradiated from the optical element 200 does not reach the cover 120, and the light irradiated by the optical element 201 can proceed without being disturbed.

The lens module 300 includes a protrusion 302 protruding from the main body 100 and a receiving portion 303 and a protrusion 302 which are accommodated in the main body 100. [ And a connecting portion 304 connecting the housing 302 and the accommodating portion 303. The protruding portion 302 includes the lens 301. [ At this time, the connecting portion 304 passes through the moving hole 211 formed in the heat sink 210, and the lens module 300 is free to move back and forth.

The movement of the lens module 300 is performed by the zoom adjusting module 500. That is, the zoom adjusting module 500 adjusts the distance between the first illumination module 200 and the lens 301 by moving the lens module 300 back and forth along the first direction. The illumination unit 10 of FIG. 2 can adjust the distance between the lens 301 and the optical element 201 to be between 3 mm and 23 mm.

The zoom adjusting module 500 includes a screw bar 530 extending in a first direction, a driving part 510 for driving the screw bar 530 to rotate, a screw bar 530 disposed on an inner circumferential surface of the screw bar 530, And a moving block 520 that moves in the first direction along the screw bar 530 and is fixed to the lens module 300. [

The driving unit 510 rotates the screw bar 530 with a kind of motor driven by electric power. When the screw bar 530 is rotated, the moving block 520 engaged with the screw bar 530 is subjected to a forward or backward force in the first direction. At this time, the moving block 520 is guided by the supporting part 540 fixed to the driving part 510 and does not rotate along the screw bar 530, but moves along the longitudinal direction of the screw bar 530.

The movable block 520 is fixed to the lens module 300 so that when the screw bar 530 rotates, the lens module 300 moves forward or backward along the screw bar 530. In this manner, the distance between the lens 301 and the optical element 201 is adjusted.

The zoom adjusting module 500 advances or retracts the lens module 300 according to the degree of tilting of the main body 100 and the degree of tilting of the main body 100 corresponds to the degree of tilting of the first sensor module 400 . The first sensor module 400 may be disposed in the main body 100 and may be disposed in the control module 600 for controlling the zoom control module 500.

The first sensor module 400 may be a sensor capable of recognizing the posture of the illumination unit 10, for example, a gyro sensor. The first sensor module 400 may sense the inclination of the direction of the first illumination module 200. That is, the first sensor module 400 recognizes the direction of the light irradiated by the first illumination module 200 by recognizing the tilted direction of the illuminating unit 10.

The first sensor module 400 recognizes the tilting of the illumination unit 10 and provides the tilted light to the control module 600. The control module 600 controls the zoom module 500 It is possible to increase the irradiation angle of the light. The first sensor module 400 provides the tilt of the illumination unit 10 to the control module 600 and the control module 600 controls the zoom module 500 It is possible to control the light irradiation angle so as to narrow and distant view by controlling.

The first sensor module 400 may be operated by the sensor button 620. That is, when the sensor button 620 is turned on, the first sensor module 400 can be recognized or the zoom control module 500 can be controlled. When the sensor button 620 is turned off, the first sensor module 400 does not recognize Or the zoom adjustment module 500 may not operate. That is, the sensor button 620 is a switch for determining the operation of the first sensor module 400 or the zoom adjusting module 500.

In addition, it is possible to determine whether the first sensor module 400 is operated according to the number of times the sensor button 620 is pressed or the speed. In this case, the number of times or the speed of controlling the operation of the first sensor module 400 may be variously modified and applied. For example, since the first sensor module 400 is not operated when the first power button 610 is depressed and the sensor button 620 is not pressed, even if the inclination value of the first direction is changed, The irradiation angle of the irradiating light does not change. When the first sensor module 400 is operated by pressing the sensor button 620, the tilting of the main body 100 is recognized. When the sensor button 620 is pressed again in this state, the sensor button 620 is pressed The irradiation angle of the light irradiated by the first illumination module 200 can be fixed. Such control can be modified in various ways.

When the sensor button 620 is turned on and the first sensor module 400 is operated, it is possible to detect the degree of inclination of the first direction from the horizontal direction.

When the tilt value in the first direction gradually increases downward, the irradiation angle of the light illuminated by the first illumination module 200 gradually increases, and when the tilt value in the first direction gradually decreases and the first direction approaches the horizontal direction , The irradiation angle of the light irradiated by the first illumination module 200 becomes smaller. The irradiation angle of the light irradiated by the first illumination module 200 can be adjusted by the lens module 300 which is moved back and forth along the first direction.

The second sensor module 330 is a sensor capable of recognizing the initial position of the lens module 300 and may include a magnet portion 331 and a position sensor 332. The position sensor 332 is provided on the movement path of the magnet portion 331 to recognize the magnetic field of the magnet portion 331 and recognize the position of the lens module 300. 2, the magnet unit 331 is installed in the lens module 300 and the position sensor 332 is installed inside the main unit 100. However, the present invention is not limited thereto, and the magnet unit 331 When the position sensor 332 is installed in the lens module 300 and the position sensor 332 can be installed on the moving path of the magnet portion 331, It can be variously modified.

The smart illumination device 1 can set a state in which the positions of the magnet portion 331 and the position sensor 332 are overlapped with each other in a basic state. The lens module 300 is received in the main body 100 and the lens 301 and the first illumination module 200 are closest to each other in a state where the magnet portion 331 and the position sensor 332 are overlapped. And the distance between the lens 301 and the optical element 201 is the shortest distance. Therefore, when the irradiation angle of the light irradiated by the first illumination module 200 is the maximum, it becomes a basic state. The basic state refers to the irradiation angle state of the light when the power source is applied and when the power source is cut off.

When the power is applied, the smart illumination device 1 irradiates light at a basic illumination angle and when the user presses the sensor button 620 to actuate the first sensor module 400, the smart illumination device 1 illuminates the first direction The illumination angle of the light illuminated by the first illumination module is adjusted according to the tilt value. When the user depresses the power button 610 again, the power can be automatically restored to the basic state.

Hereinafter, with reference to FIG. 4, the process of changing the irradiation angle of light according to the degree of tilting of the smart illumination device will be described in more detail. FIG. 4 is a view showing a state in which the irradiation angle of light changes according to the degree of tilting of the illumination unit of FIG. 1;

When the user grasps the illumination unit 10 and drives the illumination unit 10 by sequentially pressing the power button 610 and the sensor button 620 and then tilts the illumination unit 10, The angle is controlled and the length and range of light irradiation can vary. 4 (a) shows a state in which the user keeps the illumination unit 10 in a horizontal state and shines forward, and the light is irradiated in a narrow range.

That is, when the distance d1 between the optical element 201 and the lens 301 is increased, the light irradiation angle becomes smaller and the light-emitting area a becomes narrower as well.

When the user tilts the illumination unit 10 downward to illuminate the floor, the first sensor module 400 recognizes the inclination and transmits the inclination to the control module 600. 4 (b) is a view showing a state in which the illumination unit 10 is inclined downward, and the light is irradiated in a wide range with a large irradiation angle. The irradiation angle of the light irradiated by the illumination unit 10 can be increased in proportion to the degree ([theta]) in which the direction in which the light is irradiated is inclined from the horizontal direction. When the first sensor module 400 recognizes the degree of tilting of the illumination unit 10, the lens module 300 moves to narrow the distance d2 between the lens 301 and the optical element 201, As the angle increases, the light emitting area a 'also becomes wider.

When the first sensor module 400 recognizes that the tilt value detected by the first sensor module 400 is in a horizontal state at 0 °, the tilt value sensed by the first sensor module 400 is adjusted to 0 ° The illumination angle of the light irradiated by the first illumination module 200 gradually increases according to the angle. When the tilt value sensed by the first sensor module 400 exceeds 45 degrees, the irradiation angle is not further increased, and the maximum irradiation angle as shown in FIG. 4 (b) can be maintained.

When the user presses the power button 610 of the illumination unit 10 to cut off the power or presses the sensor button 620 to finish adjusting the irradiation angle of the light, the lens module 300 is rotated by the magnet unit 331 and the position sensor 332, To the overlapping position. At this time, the position of the lens module 300 is recognized by the second sensor module 330. That is, as described above, since the state in which the magnet portion 331 and the position sensor 332 are overlapped is set as the basic state of the illumination portion 10, when the power is turned off, the illumination portion 10 can be restored to the basic state will be.

Hereinafter, the cradle of the smart illumination device will be described in detail with reference to Figs. 5 to 7. Fig.

FIG. 5 is a perspective view showing a cradle of a smart lighting device according to an embodiment of the present invention, FIG. 6 is a longitudinal sectional view of the cradle of FIG. 5, and FIG. It is an operation diagram.

The cradle 20 allows the illumination unit 10 to be mounted and functions as a stand or an interior lamp. 5, the cradle 20 includes a stand 24 having a front surface and an input button 25 having a cylindrical shape and capable of directly controlling power, rotation, and inclination, a main body 100 fixed to the stand 24, And a rotation module rotatably coupled to the stand 24.

The cradle 20 is configured such that at least a part of a spherical rotary module 23a protrudes from the upper end of the stand 24 and the rest of the rotary module 23a except for the protruding portion is accommodated in the stand 24. A control unit (not shown) for controlling the movement of the cradle 20 is accommodated in the stand 24 so that power is supplied to the cradle 20 and the first motor 22b or the second motor 23b It is possible to provide a driving force.

The rotating module 23a has a mounting hole 21 in which a rotational axis is formed in a horizontal direction and in which the main body 100 is inserted at the center, a main body 100 is fixed to the bottom of the mounting hole 21, As shown in Fig. The inner diameter of the mounting hole 21 can be formed to be the same as the outer peripheral surface of the main body 100 so that the illuminating portion 10 can be seated and mounted as if it is sandwiched by the cradle 20 and can be accommodated more securely.

5 and 6, the rotary plate 22a is a structure for horizontally rotating the main body 100 mounted on the cradle 20, and the rotation module 23a is mounted on the cradle 20 The main body 100 is tilted at a predetermined angle with respect to the longitudinal direction. Each of the rotary plate 22a and the rotary module 23a may be provided with a motor for controlling the rotation and a motor for controlling the inclination. That is, the rotary plate 22a is connected to the first motor 22b, and when the first motor 22b is driven, the rotary plate 22a rotates in the horizontal direction with the vertical axis as the rotary axis. Referring to FIG. 7A, the first motor 22b may be vertically connected to one side of the lower surface of the rotary plate 22a, and the first motor 22b and the rotary plate 22a are engaged with each other using a screw. More specifically, a screw thread meshing with the first motor 22b is formed on the lower surface of the rotary plate 22a, and when the first motor 22b rotates, it is engaged with the thread of the rotary plate 22a to rotate the rotary plate 22a . For example, when the first motor 22b rotates in the counterclockwise direction, the rotary plate 22a rotates clockwise and rotates the illumination unit 10 mounted on the rotary plate 22a clockwise together.

The rotation module 23a is connected to the second motor 23b so that when the second motor 23b is driven, the rotation module 23a rotates in the vertical direction with the horizontal direction as the rotation axis. At this time, the rotation module 23a can be connected to the second motor 23b using the second gear 23c, so that even if the second motor 23b is not directly connected to the rotation axis of the rotation module 23a, 23a. Even if the second motor 23b is housed in the lower end of the stand 24 as shown in Fig. 7B, the second motor 23b is rotated through the second gear 23c coupled to one side of the rotation module 23a, And when the second motor 23b rotates, it engages with the second gear 23c so that the rotation module 23a can rotate. More specifically, when the second motor 23b rotates in the counterclockwise direction, the second gear 23c meshes with the second motor 23b and rotates in the clockwise direction, and the rotation coupled with the second gear 23c The module 23a is also rotated clockwise.

The connection terminal 26 may be formed on the upper surface of the rotary plate 22a. The connection terminal 26 is a terminal for electrically connecting the cradle 20 and the illumination unit 10. When the cradle 20 and the main body 100 are connected through the connection terminal 26, Is activated and the first illumination module 200 can be deactivated. Activation and deactivation can be distinguished by whether power is applied or not. The first illumination module 200 or the second illumination module 250 is set to be in a state ready for irradiating light when power is applied thereto and is referred to as an activation. It is called inactivation.

As described above, when the cradle 20 and the illumination unit 10 are connected, the second illumination module 250 is activated, and the smart illumination unit 1 becomes ready to perform a role of a stand or an interior light.

Hereinafter, with reference to FIGS. 8 to 9, the operation of the smart lighting device according to an embodiment of the present invention will be described in detail.

FIG. 8 illustrates an operation of a smart lighting device according to an embodiment of the present invention, and FIG. 9 illustrates a screen of a smart device that controls a smart lighting device according to an exemplary embodiment of the present invention.

As shown in Fig. 8, the illuminating unit 10 can be seated in the cradle 20. The rear end of the main body 100 may be seated on the mounting hole 21 of the cradle 20 so that the rotary plate 22a and the rear end face of the main body 100 can be in contact with each other. When the main body 100 is mounted on the cradle 20, the first illumination module 200 may be deactivated and the second illumination module 250 may be activated. That is, when the main body 100 is not mounted on the cradle 20, power is applied only to the first illumination module 200 through the battery 700 to activate the first illumination module 200, The module 250 is deactivated and when the main body 100 is mounted on the cradle 20, the power supplied from the battery 700 is cut off and the power is supplied from the cradle 20, And the second illumination module 250 can be activated. When the second illumination module 250 is activated, it can be used as a stand or an interior lamp.

Figs. 8A to 8C are diagrams for explaining a case where the lighting unit 10 of Fig. 1 is seated on the cradle 20 of Fig. 5 and operates as a stand or an interior lamp in a state in which the second lighting module 250 is activated Specifically.

8 (a), when the main body 100 is mounted on the cradle 20, the first illumination module 200 is deactivated and only the second illumination module 250 is activated. That is, when the second illumination module 250 irradiates light in the second direction, the light passes through the light-observation window 110 and is irradiated as B. At this time, the user may directly control the rotation of the rotary plate 22a or the rotation module 23a through an input button (see 25 in FIG. 5) formed on the outside of the stand 24, d, indirect control may be performed using a smart device.

Referring to FIG. 8 (b), light irradiated as shown in FIG. 8 (a) is emitted in the opposite direction B 'as the rotating plate 22a is driven and the illumination unit 10 rotates by 180 . 8 (c), the light can be irradiated as B " in a state in which the rotation module 23a is inclined and the illumination unit 10 is inclined together. The angle may be set between 0 and 72. This range is set within a range in which the center of gravity is not shaken when the illumination unit 10 is mounted on the cradle 20 and even if the rotation module 23a is rotated as much as possible , The rotation of the cradle 20 can be stopped when the angle is equal to or larger than 72 DEG, so that there is no possibility that the cradle 20 is collapsed while the operation of tilting the illumination unit 10 is performed.

The second illumination module 250 is attached to the support plate 251 inside the body 100 so that when the body 100 is received in the cradle 20, It can be hidden inside the mounting hole (see 21 in Fig. 5). In other words, since the light irradiated by the second illumination module 250 can be prevented from directly touching the user's eyes, the second illumination module 250 can function indirectly, and is useful for use in reading, etc., and a mild atmosphere can be produced Mood or the like.

As shown in FIG. 9, the smart lighting device 1 according to an embodiment of the present invention can be operated in conjunction with a smart device when used as a stand or a room. More specifically, the user can remotely control the power of the smart lighting device 1 through the smart device screen, and adjust the color and brightness of the second lighting module 250. The rotation of the cradle 20 may be directly controlled through the input button 25 outside the cradle 20 as described above or remotely controlled to the smart device screen.

9 (a) is a diagram showing a first screen for controlling the smart illumination device 1. In Fig. The user can operate the second illumination module 250 by controlling the power source on the screen of the smart device and can set the color, brightness, rotation and tilt of the second illumination module 250 by touching the respective menu buttons .

As shown in FIG. 9B, when the application of the smart device is activated to enter the 'Color' menu, the RGB color table is displayed on the screen of the smart device, so that the light emitted by the second lighting module 250 is visually And it is very easy to select the color. 9 (c) and 9 (d), when the user touches the 'Rotation' menu or the 'Pantilt' menu to enter the respective menus, The degree of rotation of the rotary plate 22a can be adjusted by turning the wheel as shown in FIG. 9 (d), and the rotary module 23a is rotated by the touch of the goniometer displayed on the screen of the smart device, Can be adjusted.

As described above, when the degree of rotation of the rotary plate 22a and the angle of inclination of the rotary module 23a are visually checked and controlled on the screen of the smart device, The smart illumination device 1 can be controlled much more effectively than the first embodiment. In addition, the smart lighting device 1 can be conveniently remotely controlled through an application even at a long distance.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, You will understand. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

1: Smart lighting device
10: illumination part 20: cradle
21: mounting hole 22a: spindle
22b: first motor 23a: rotation module
23b: second motor 23c: second gear
24: Stand 25: Input button
26: connection terminal 100:
110: optical window 120: cover part
200: first lighting module 201: optical element
202: element substrate 210: heat sink
211: moving hole 250: second lighting module
251: Support plate 300: Lens module
301: lens 302:
303: receiving portion 304: connecting portion
330: second sensor module 331: magnet portion
332: Position sensor 400: First sensor module
500: zoom adjustment module 510:
520: Moving block 530: Screw bar
540: Support part 600: Control module
610: Power button 620: Sensor button
700: Battery

Claims (11)

A body portion;
A first illumination module accommodated in the main body and irradiating light in a first direction;
A lens module installed at a front end of the first illumination module to adjust an irradiation angle of light;
A first sensor module installed in the main body and detecting a degree of inclination of the first direction from a horizontal direction; And
And a zoom adjusting module for moving the lens module back and forth along the first direction according to a slope value of the first direction sensed by the first sensor module to adjust an irradiation angle of light irradiated by the first illumination module Smart lighting device. The method according to claim 1,
Wherein the zoom module adjusts an irradiation angle of light radiated by the first illumination module by moving the lens module when the inclination value of the first direction gradually increases downward, The illumination angle of the light illuminated by the first illumination module is gradually reduced when the first direction is in the horizontal direction. 3. The method of claim 2,
Wherein the lens module comprises a convex lens,
The zoom module according to claim 1, wherein when the inclination value of the first direction is gradually increased downward, the zoom module is brought close to the first illumination module, and the tilt value of the first direction is gradually decreased, And adjusts the lens module to be away from the first illumination module when it is close. The method according to claim 1,
The zoom adjusting module may further include a screw bar extending in the first direction, a driving part for driving the screw bar to rotate, and a screw thread engaging the screw bar on an inner circumferential surface through which the screw bar passes, And a moving block that is moved and fixed to the lens module. The method according to claim 1,
And a second sensor module installed in the main body unit and recognizing the position of the lens module including the magnet part and the position sensor, wherein the magnet part is installed in one of the lens module or the main body part, Wherein the module is installed on the other one of the smart part and the position sensor, and the position sensor recognizes the magnetic field of the magnet part and recognizes the position of the lens module. 6. The method of claim 5,
Wherein the zoom adjusting module moves the lens module to a position where the magnet unit and the position sensor overlap when the first illumination module is powered off. The method according to claim 1,
Wherein the light emitted from the second illumination module is irradiated in a second direction different from the first direction and irradiated outside the main body portion. 8. The method of claim 7,
Wherein the body portion is formed with a light irradiation window of a transparent or semi-transparent material on a side portion thereof, and the second illumination module is installed inside the light projection window. 8. The method of claim 7,
And a cradle in which the main body portion is mounted,
Wherein the first illumination module is deactivated and only the second illumination module is activated when the body portion is mounted on the cradle. 10. The method of claim 9,
The cradle includes a stand on which a floor is supported, and a rotation module to which the main body section is fixed and is rotatably coupled to the stand. 11. The method of claim 10,
Wherein the rotation module includes a rotary plate having a rotation axis formed in a horizontal direction and a center hole formed in the center of the rotation module, and a rotatable plate rotatable in a horizontal direction with the body fixed to the bottom of the fixation hole.

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