CN115727277B - Partition type soft light and assembly method thereof - Google Patents

Abstract

The present invention provides a partitioned soft light, comprising: the LED lamp comprises a lamp shade, LED lamp panels, a control device, a heat radiating device and a support, wherein the lamp shade is rotatably arranged on the support, the LED lamp panels, the control device and the heat radiating device are all arranged in the lamp shade, the number of the LED lamp panels is multiple, and the LED lamp panels are distributed side by side. The control device comprises a regulation and control table and a controller arranged in the lampshade, and the controller is in remote communication connection with the regulation and control table and transmits received signals to the LED lamp panel; the heat dissipation device is arranged on the backlight surface of the LED lamp panel. The lamp shade is provided with a connecting panel, the connecting panel is provided with a power interface, and the connecting panel is electrically connected with the controller, the LED lamp panel and the heat dissipation device. The partition type soft light can increase the functions of the soft light so as to meet the requirements of different scenes.

Description

Partition type soft light and assembly method thereof

Technical Field

The invention relates to the technical field of lighting equipment, in particular to a partition type soft light and an assembly method thereof.

Background

The soft light is a photographic light which has soft light and no obvious shadow, is suitable for reflecting the shape and color of an object and gives people a soft and fine sense. The light emitted by the flash lamp can be softened, so that the photo looks more natural. The principle is that the direct light of a stiff flash lamp is converted into soft diffuse light through high-temperature-resistant semitransparent plastic, and the unpleasant high light spots on human images and other photographed objects are eliminated, so that your photo is beautiful and natural as the photo taken in a film studio.

The soft light on the market mostly adopts a whole luminescent plate, and the luminescent plate wholly emits light after the power is connected, and its function is single, is difficult to satisfy the needs of multiple scene. Therefore, how to design a zoned soft light, the luminous plate of the zoned soft light is divided into a plurality of areas which can be controlled independently, and then the brightness and the color of each area are adjusted, so that a plurality of light modes are realized, the functions of the soft light are increased, and the requirements of different scenes are met, which is a technical problem to be solved by the technicians in the field.

Disclosure of Invention

The invention aims to overcome the defects in the prior art and provides a partition type soft light and an assembly method thereof so as to increase the function of the soft light and meet the requirements of different scenes.

The aim of the invention is realized by the following technical scheme:

a zoned soft light, comprising: the LED lamp comprises a lamp shade, LED lamp panels, a control device, a heat radiating device and a bracket, wherein the lamp shade is rotatably arranged on the bracket, the LED lamp panels, the control device and the heat radiating device are all arranged in the lamp shade, the number of the LED lamp panels is multiple, and the LED lamp panels are distributed side by side;

the control device comprises a regulation and control table and a controller arranged in the lampshade, and the controller is in remote communication connection with the regulation and control table and transmits received signals to the LED lamp panel; the heat dissipation device is arranged on the backlight surface of the LED lamp panel;

the lamp shade is provided with a connecting panel, the connecting panel is provided with a power interface, and the connecting panel is electrically connected with the controller, the LED lamp panel and the heat radiating device.

In one embodiment, the heat dissipating device comprises a heat sink and a heat dissipating fan, the heat sink comprises a plurality of heat dissipating fins, the heat dissipating fins are arranged at intervals, the heat dissipating fins are attached to the backlight surface of the LED lamp panel, and the heat dissipating fan is attached to the heat dissipating fins of the heat sink.

In one embodiment, the bracket is provided with a locking assembly, and the lampshade is arranged on the bracket through the locking assembly;

the lock assembly includes: the device comprises a protective cover, a friction disc, an elastic clamping piece, a locking bolt and a locking handle; the protective cover is sleeved on the support, the friction disc is fixedly arranged on the lamp shade and is arranged on the support in a rotating way around a rotating shaft, the elastic clamping piece is arranged on the support, the locking bolt penetrates through the elastic clamping piece and the support, and the locking bolt is in threaded connection with the locking handle;

the friction disc is provided with an outer extension edge, the elastic clamping piece is provided with a clamping gap, the outer extension edge is positioned in the clamping gap, the tail end of the locking bolt is provided with a baffle, and the baffle is propped against the elastic clamping piece.

In one embodiment, the connection panel includes a power connector detachably connected to the power interface;

the power connector comprises a plug cylinder and a holding sleeve, and the holding sleeve is sleeved on the plug cylinder in a sliding manner;

the power interface includes: the device comprises a base, a sliding cylinder, a clamping ring and an unlocking piece; an inner cylinder is arranged in the base, the sliding cylinder is arranged in the base in a sliding way through a first elastic piece, and the sliding cylinder is sleeved outside the inner cylinder; the clamping ring is arranged in the base in a sliding manner through a second elastic piece, a first-stage clamping tooth is arranged on the clamping ring, and a first-stage clamping groove matched with the first-stage clamping tooth is formed in the sliding barrel; the inner cylinder is provided with a second-level clamping groove, and the plug-in cylinder is provided with an elastic clamping block matched with the second-level clamping groove;

the unlocking piece is provided with a cam, and the cam is rotatably arranged on the unlocking piece through a torsion spring.

In one embodiment, the unlocking piece comprises a pressing portion and a propping end, wherein the pressing portion is located on the outer side of the base, and the propping end is propped against the clamping ring.

In one embodiment, the plugging cylinder is provided with a limit groove, the holding sleeve is provided with a limit ring, and the limit ring is slidably arranged in the limit groove.

In one embodiment, the slide cylinder is provided with a blocking ring, and the holding sleeve is propped against the blocking ring;

the first elastic piece is of a spring structure, one end of the first elastic piece is propped against the blocking ring, and the other end of the first elastic piece is propped against the base.

In one embodiment, the base is provided with an anti-falling flange, and the blocking ring is propped against the anti-falling flange.

The method for assembling the partition type soft light is based on the partition type soft light, and comprises the following steps of:

installing a plurality of LED lamp panels into the lampshade, wherein the LED lamp panels are distributed side by side;

attaching the radiator to the backlight surface of the LED lamp panel, wherein radiating fins of the radiator are in contact with the LED lamp panel; attaching a heat dissipating fan to a heat sink of the heat sink;

placing the controller into the lampshade, wherein a plurality of LED lamp panels are electrically connected with the controller;

the connection panel is electrically connected with the controller, the LED lamp panel and the cooling fan, and is fixedly arranged on the lamp shade to complete the lamp shade packaging;

and the regulation and control platform is connected with the controller in a wireless pairing mode.

In conclusion, the partition type soft light can increase the functions of the soft light and meet the requirements of different scenes.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are needed in the embodiments will be briefly described below, it being understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and other related drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of a partitioned soft light of the present invention;

FIG. 2 is an exploded schematic view of the zoned soft light of FIG. 1;

FIG. 3 is a schematic diagram of the connection between the components of the zoned soft light of the present invention;

FIG. 4 is a schematic diagram of a heat sink for a zoned soft light;

FIG. 5 is a schematic view of the lock assembly shown in FIG. 2;

FIG. 6 is an exploded view of the lock assembly shown in FIG. 5;

FIG. 7 is a schematic diagram of a power connector and a power interface;

FIG. 8 is a partial schematic view of the power connector shown in FIG. 7;

FIG. 9 is a partial cross-sectional view of the power connector shown in FIG. 7;

FIG. 10 is an exploded view of the power interface of FIG. 7;

FIG. 11 is a cross-sectional view of the power interface shown in FIG. 7;

FIG. 12 is a schematic diagram showing the mating relationship between a power connector and a power interface when plugged;

FIG. 13 is a schematic diagram showing the state of the power connector and the power interface during the primary unlocking process;

fig. 14 is a schematic diagram showing the state of the power connector and the power interface in the secondary unlocking process.

Detailed Description

In order that the invention may be readily understood, a more complete description of the invention will be rendered by reference to the appended drawings. The drawings illustrate preferred embodiments of the invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

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

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

The present invention provides a zoned soft light 10, as shown in fig. 1 and 2, comprising: the lamp shade 100, the LED lamp panel 200, the control device 300 (shown in FIG. 3), the heat sink 400 (shown in FIG. 3), and the bracket 500. The lamp shade 100 is rotatably arranged on the bracket 500, the LED lamp panels 200, the control device 300 and the heat dissipation device 400 are all arranged in the lamp shade 100, the number of the LED lamp panels 200 is multiple, and the LED lamp panels 200 are distributed side by side.

As shown in fig. 3, the control device 300 includes a control console 310 and a controller 320 disposed in the lamp shade 100, and the controller 320 is connected with the control console 310 in a remote communication manner and transmits a received signal to the LED lamp panel 200. The heat sink 400 is disposed on the backlight surface of the LED lamp panel 200. The connection relationship between the components is shown in fig. 3; in use, the console 310 may be a remote control with an entity or a mobile phone program without an entity.

The lamp shade 100 is provided with a connection panel 110, the connection panel 110 is provided with a power interface 600 (shown in fig. 7), and the connection panel 110 is electrically connected to the controller 320, the LED lamp panel 200 and the heat sink 400.

When the LED lamp panel is used, an external power supply supplies power to the soft light lamp 10 and the internal devices thereof through the connection panel 110, a user sends a wireless signal to the controller 320 through the regulation and control platform 310, and the controller 320 regulates and controls the brightness, color, flashing time and the like of the LED lamp panel 200 after receiving the signal. Because the plurality of LED lamp panels 200 are independent of each other, the brightness and color of each LED lamp panel 200 can be controlled independently.

Thus, by combining, the partitioned soft light 10 of the present invention can achieve a plurality of light modes, including: white light mode, adjustable light intensity and color temperature; the color light mode can adjust hue, saturation and light intensity, and realize adjustable color; the light effect mode can simulate various light effects such as candles, lightning, breathing lamps, warning lamps and the like; dazzle color mode: the LED lamp panel 200 can be subjected to color switching, color replacement, color gradual change and unidirectional movement, so that multi-lamp interconnection is realized. Of course, the user can freely edit and control each LED lamp panel 200 through the adjusting and controlling table 310 to meet the use requirements of different scenes.

In this embodiment, as shown in fig. 4, the heat dissipating device 400 includes a heat sink 410 and a heat dissipating fan 420, the heat sink 410 includes a plurality of heat dissipating fins 411, the plurality of heat dissipating fins 411 are arranged at intervals, the heat dissipating fins 411 are attached to the back surface of the LED lamp panel 200, and the heat dissipating fan 420 is attached to the heat dissipating fins 411 of the heat sink 410. When in use, the heat generated by the LED lamp panel 200 is transferred to the heat sink 411, and the heat dissipation fan 420 promotes the air between two adjacent heat sinks 411 to accelerate the flow, so that the heat sink 411 can better exchange heat with the surrounding air.

Further, the present invention improves the bracket 500 for the convenience of adjusting the direction of illumination of the soft light 10 during use. The method comprises the following steps:

as shown in fig. 5 and 6, a locking unit 510 is provided on the bracket 500, and the lamp housing 100 is mounted on the bracket 500 through the locking unit 510. Wherein, lock assembly 510 includes: a protective cover 511, a friction disk 512, an elastic clamp 513, a locking bolt 514, and a lock handle 515. The protective cover 511 is sleeved on the bracket 500, and the protective cover 511 plays a role in protecting the locking assembly 510. The friction plate 512 is fixedly arranged on the lamp shade 100 and is rotatably arranged on the bracket 500 around the rotation shaft 516, that is, when the lamp shade 100 rotates, the friction plate 512 rotates on the bracket 500 around the rotation shaft 516. The elastic clamping member 513 is disposed on the bracket 500, the locking bolt 514 penetrates the elastic clamping member 513 and the bracket 500, and the locking bolt 514 is in threaded connection with the locking handle 515.

The friction plate 512 is provided with an outer edge 512a, the elastic clamping member 513 is provided with a clamping gap, the outer edge 512a is positioned in the clamping gap, the end of the locking bolt 514 is provided with a blocking piece, and the blocking piece is abutted against the elastic clamping member 513.

When in use, the lampshade 100 is adjusted to a proper direction, and then the locking handle 515 is rotated, and the locking handle 515 is in threaded connection with the locking bolt 514, so that the locking bolt 514 is pulled to be close to the elastic clamping piece 513, the baffle piece on the locking bolt is contacted and abutted on the elastic clamping piece 513, and a pressing force is provided for the elastic clamping piece 513. After being stressed, the clamping gap of the elastic clamping member 513 is reduced, so that the outer edge 512a in the clamping gap is clamped, and the friction disc 512 cannot rotate, so that the lampshade 100 is fixed. When the irradiation direction needs to be adjusted again, the direction of the lamp cover 100 can be adjusted again by unscrewing the locking handle 515, so that the friction between the elastic clamping member 513 and the outer edge 512a is reduced.

Furthermore, in the practical use process, the conventional wiring mode is not stable enough, the joint and the interface which are connected with each other are easily torn off carelessly, and the joint and the interface can become loose after long-term use, so that poor contact is caused. In the prior art, there is a wiring mode in which a locking member such as a buckle is arranged between the connector and the interface, but the wiring mode still has the problem of easy false touch unlocking. To this end, the zoned soft light 10 of the present invention is also particularly modified to address the above-described problems.

Specifically, as shown in fig. 7, 8 and 9, the connection panel 110 includes a power connector 700, and the power connector 700 is detachably connected to the power interface 600. The power connector 700 includes a socket cylinder 710 and a grip sleeve 720, wherein the grip sleeve 720 is slidably sleeved on the socket cylinder 710.

As shown in fig. 7, 10 and 11, the power interface 600 includes: base 610, slide 620, latch 630 and release 640. The inner cylinder 611 is disposed in the base 610, the sliding cylinder 620 is slidably disposed in the base 610 through the first elastic member 621, and the sliding cylinder 620 is sleeved outside the inner cylinder 611. The clamping ring 630 is slidably disposed in the base 610 through the second elastic member 631, the clamping ring 630 is provided with a first-stage latch 632, and the slide cylinder 620 is provided with a first-stage latch 622 matching with the first-stage latch 632. The inner cylinder 611 is provided with a secondary clamping groove 612, and the plugging cylinder 710 is provided with an elastic clamping block 711 (as shown in fig. 9) matched with the secondary clamping groove 612. The unlocking member 640 is provided with a cam 641, and the cam 641 is rotatably provided on the unlocking member 640 by a torsion spring (not shown).

It is emphasized that the sliding direction of the sliding cylinder 620 and the sliding direction of the clamping ring 630 in the base 610 are different, the sliding cylinder 620 slides along the axial direction of the inner cylinder 611 (the sliding cylinder 620 cannot rotate during sliding), the clamping ring 630 slides perpendicular to the axial direction of the inner cylinder 611, and the sliding cylinder 620 penetrates the clamping ring 630. Thus, during the sliding process, the sliding cylinder 620 and the clamping ring 630 interfere, and when the clamping ring 630 and the sliding cylinder 620 are clamped with each other, the primary locking is realized.

In the present invention, the power interface 600 and the power connector 700 cooperate to form a double locking, specifically, the slide cylinder 620 and the clamping ring 630 cooperate to form a primary locking of the power connector 700, and the elastic clamping block 711 cooperates with the secondary clamping groove 612 of the inner cylinder 611 to form a secondary locking of the power connector 700. When unlocking, the unlocking operation of the primary locking is finished firstly, and the secondary locking can be unlocked. Of course, it is also understood that primary locking is a safety measure for secondary locking. The specific working principle will be explained below.

In this embodiment, as shown in fig. 10, the unlocking member 640 includes a pressing portion 642 and a holding end 643, the pressing portion 642 is located outside the base 610, and the holding end 643 abuts against the clamping ring 630. When unlocking, an operator presses the unlocking piece 640, so that the top holding end 643 pushes the clamping ring 630 to slide, and the cam 641 is close to the inner cylinder 611. The specific working principle will be explained below.

In this embodiment, as shown in fig. 9, the socket cylinder 710 is provided with a limiting groove 712, the grip sleeve 720 is provided with a limiting ring 721, and the limiting ring 721 is slidably disposed in the limiting groove 712. The grip sleeve 720 can only slide freely along the socket cylinder 710 by the cooperation of the limiting ring 721 and the limiting groove 712, and the sliding distance is fixed. This is designed to provide the necessary movement space for the grip cover 720.

Preferably, as shown in fig. 10, a blocking ring 623 is provided on the slide cylinder 620, and the grip sleeve 720 abuts against the blocking ring 623. And the first elastic element 621 is a spring structure, one end of the first elastic element 621 abuts against the blocking ring 623, and the other end abuts against the base 610.

The following describes the operation principle of the power connector 700 and the power interface 600 according to the present invention with reference to the above-described configuration:

when the power connector 700 is plugged into the power interface 600, primary locking and secondary locking are simultaneously completed, thereby achieving stable connection. The method comprises the following steps: an operator holds the plug cylinder 710 on the holding sleeve 720 and pushes the plug cylinder to plug into the inner cylinder 611 of the base 610; at this time, the holding sleeve 720 abuts against the blocking ring 623 of the sliding barrel 620, so as to push the sliding barrel 620 to slide, the first elastic element 621 is compressed, when the sliding barrel 620 slides to the first stage clamping groove 622 to correspond to the first stage clamping tooth 632, the clamping ring 630 slides under the action of the second elastic element 631, and the first stage clamping tooth 632 is clamped in the first stage clamping groove 622, so that the first stage locking is realized. Meanwhile, the plugging cylinder 710 enters the inner cylinder 611, when the primary latch 632 and the primary latch 622 are clamped with each other, the elastic latch 711 of the plugging cylinder 710 also just slides to the secondary latch 612, and under the action of the self elastic force, the elastic latch 711 is clamped with the slot wall of the secondary latch 612, so that secondary locking is realized. At this moment, the lower end edge of the sliding cylinder 620 will abut against the cam 641, so that the cam 641 deflects against the torsion spring, and the protruding end of the cam 641 is no longer directed to the secondary clamping groove 612 (as shown in fig. 12);

when the power connector 700 needs to be pulled out, an operator needs to unlock the primary lock first to unlock the secondary lock further, and after the secondary lock is completely unlocked, the power connector 700 can be separated from the power interface 600. The specific process is as follows:

first, an operator presses the pressing portion 642 of the unlocking member 640, so that the top end 643 abuts against and pushes the clamping ring 630 to slide against the elastic force of the second elastic member 631; meanwhile, the cam 641 on the unlocking member 640 is close to the inner cylinder 611, and as the protruding end of the cam 641 does not point to the secondary clamping groove 612, the cam 641 is close to the inner cylinder 611 while overcoming the torsion spring to perform further deflection action under the abutting of the outer wall of the inner cylinder 611 or the edge of the sliding cylinder 620. When the latch 630 slides a certain distance, the primary latch 632 of the latch 630 is disengaged from the primary latch 622 (as shown in fig. 13), the sliding cylinder 620 will slide reversely under the elastic force of the first elastic element 621, so that the primary latch 622 and the primary latch 632 are dislocated, and the primary lock is unlocked;

then, the operator releases the unlocking member 640, the unlocking member 640 returns under the action of elastic force, the cam 641 moves away from the inner cylinder 611 along with the unlocking member 640, and at this time, the cam 641 returns and deflects under the action of the torsion spring until the protruding end of the cam 641 points to the secondary clamping groove 612 (as shown in fig. 14);

then, the operator presses the unlocking member 640 again, and the unlocking member 640 still causes the latch ring 630 to slide and the cam 641 to approach the inner cylinder 611. At this time, the sliding of the latch 630 does not have any influence, and the cam 641 approaches the inner cylinder 611, so that the protruding end thereof enters the secondary slot 612 and pushes the elastic latch 711. After the elastic clamping block 711 is separated from the secondary clamping groove 612, the secondary locking is unlocked, and an operator can smoothly draw the power connector 700 out of the power interface 600.

It should be noted that, the connection structure between the socket cylinder 710 and the grip sleeve 720, which is specifically designed to match the use of the slide cylinder 620, adopts a limiting ring 721 and a limiting groove 712. Specifically, when plugging, although the grip sleeve 720 can slide, the sliding range is limited, i.e. after the limiting ring 721 of the grip sleeve 720 abuts against the groove wall at one side of the limiting groove 712, the operator can drive the plugging cylinder 710 through the grip sleeve 720; when the primary latch 632 is unlocked, the sliding barrel 620 slides under the action of the first elastic element 621 after the primary latch 632 is disengaged from the primary latch 622, at this time, the socket barrel 710 is kept still, the sliding barrel 620 is required to push the holding sleeve 720, so that the holding sleeve 720 can slide relatively on the socket barrel 710, and the limiting slot 712 just provides such a movable space for the holding sleeve 720 that the limiting ring 721 can slide to the other side of the limiting slot 712 (as shown in fig. 14) under the pushing of the sliding barrel 620. That is, the connection structure of the stop collar 721 and the stop groove 712 cooperates with the use of the slide cylinder 620, thereby realizing the following two features: firstly, the plugging of the plugging cylinder 710 is not affected, and the pushing of the sliding cylinder 620 is not affected to complete primary locking; secondly, the slide 620 can be provided with the necessary moving space when the first stage is unlocked.

It is further noted that the deflecting action of the cam 641 is critical to achieving the unlocking sequence. Specifically, when not inserted, the protruding end of the cam 641 is directed to the secondary card slot 612; when the plug-in lock is locked, the lower end edge of the sliding cylinder 620 abuts against the cam 641, so that the cam 641 is deflected, and the protruding end of the cam 641 is not directed to the secondary clamping groove 612 any more. Because of the deflection of the cam 641, the protruding end of the cam 641 further abuts against the outer wall of the inner cylinder 611 during primary unlocking, and the cam 641 can only continue to perform deflection, so that secondary unlocking cannot be realized by the cam 641 at the moment. After the first-stage unlocking, the cam 641 is not supported by the sliding cylinder 620, and the cam 641 is righted under the action of the torsion spring, and the protruding end of the cam 641 points to the second-stage clamping groove 612 again. At this time, the unlocking member 640 is pressed, and the protruding end of the cam 641 pushes the elastic clamping block 711 to be separated from the secondary clamping groove 612, so as to realize secondary unlocking.

In one embodiment, the base 610 (as shown in fig. 12) is provided with a disengagement preventing edge 613, and the blocking ring 623 abuts against the disengagement preventing edge 613. The release flange 613 is configured to abut against the blocking ring 623, thereby preventing the sliding tube 620 from sliding out of the base 610.

In the present invention, based on the above-mentioned partitioned soft light 10, there is provided an assembling method of a partitioned soft light, which specifically includes the following steps:

step one, a plurality of LED lamp panels 200 are installed in a lampshade 100, and the LED lamp panels 200 are distributed side by side;

step two, the heat sink 410 is attached to the back surface of the LED lamp panel 200, the heat sink 411 of the heat sink 410 is in contact with the LED lamp panel 200, and the heat dissipation fan 420 is attached to the heat sink 411 of the heat sink 410. After the bonding, the heat of the LED lamp panel 200 is transferred to the heat sink 411, and the heat dissipation of the heat sink 411 can be accelerated by the heat dissipation fan 420;

step three, the controller 320 is disposed in the lamp shade 100, and the plurality of LED lamp panels 200 are electrically connected with the controller 320. That is, the controller 320 is individually connected to each LED lamp panel 200, which is advantageous for transmitting control signals;

step four, the connection panel 110 is electrically connected with the controller 320, the LED lamp panel 200 and the cooling fan 420, and the connection panel 110 is fixedly arranged on the lampshade 100 to complete the encapsulation of the lampshade 100, so that after the connection, the connection panel 110 can supply power to the controller 320, the LED lamp panel 200 and the cooling fan 420;

and fifthly, the regulation and control table 310 is in wireless pairing connection with the controller 320, and after pairing, the partition type soft light 10 can be remotely controlled through the regulation and control table 310, so that the light mode of the partition type soft light 10 can be switched.

In summary, the zoned soft light 10 of the present invention can control the brightness and color of each zone independently to realize multiple light modes, thereby increasing the functions of the soft light 10 and meeting the needs of different scenes.

The above examples illustrate only a few embodiments of the invention, which are described in detail and are not to be construed as limiting the scope of the invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

Claims (8)

1. A zoned soft light comprising: the LED lamp comprises a lamp shade, LED lamp panels, a control device, a heat radiating device and a bracket, wherein the lamp shade is rotatably arranged on the bracket, the LED lamp panels, the control device and the heat radiating device are all arranged in the lamp shade, the number of the LED lamp panels is multiple, and the LED lamp panels are distributed side by side;

the control device comprises a regulation and control table and a controller arranged in the lampshade, and the controller is in remote communication connection with the regulation and control table and transmits received signals to the LED lamp panel; the heat dissipation device is arranged on the backlight surface of the LED lamp panel;

the lamp shade is provided with a connecting panel, the connecting panel is provided with a power interface, and the connecting panel is electrically connected with the controller, the LED lamp panel and the heat dissipation device;

the connecting panel comprises a power connector which is detachably connected with the power interface;

the power connector comprises a plug cylinder and a holding sleeve, and the holding sleeve is sleeved on the plug cylinder in a sliding manner;

the power interface includes: the device comprises a base, a sliding cylinder, a clamping ring and an unlocking piece; an inner cylinder is arranged in the base, the sliding cylinder is arranged in the base in a sliding way through a first elastic piece, and the sliding cylinder is sleeved outside the inner cylinder; the clamping ring is arranged in the base in a sliding manner through a second elastic piece, a first-stage clamping tooth is arranged on the clamping ring, and a first-stage clamping groove matched with the first-stage clamping tooth is formed in the sliding barrel; the inner cylinder is provided with a second-level clamping groove, and the plug-in cylinder is provided with an elastic clamping block matched with the second-level clamping groove;

the unlocking piece is provided with a cam, and the cam is rotatably arranged on the unlocking piece through a torsion spring.

2. The partitioned soft light of claim 1, wherein the heat sink comprises a heat sink and a heat dissipating fan, the heat sink comprises a plurality of heat dissipating fins, the plurality of heat dissipating fins are arranged at intervals, the heat dissipating fins are attached to the backlight surface of the LED lamp panel, and the heat dissipating fan is attached to the heat dissipating fins of the heat sink.

3. The partitioned soft light of claim 1, wherein the bracket is provided with a locking assembly, and the lampshade is mounted on the bracket through the locking assembly;

the lock assembly includes: the device comprises a protective cover, a friction disc, an elastic clamping piece, a locking bolt and a locking handle; the protective cover is sleeved on the support, the friction disc is fixedly arranged on the lamp shade and is arranged on the support in a rotating way around a rotating shaft, the elastic clamping piece is arranged on the support, the locking bolt penetrates through the elastic clamping piece and the support, and the locking bolt is in threaded connection with the locking handle;

the friction disc is provided with an outer extension edge, the elastic clamping piece is provided with a clamping gap, the outer extension edge is positioned in the clamping gap, the tail end of the locking bolt is provided with a baffle, and the baffle is propped against the elastic clamping piece.

4. The partitioned soft light of claim 1, wherein the unlocking member comprises a pressing portion and a holding end, the pressing portion is located outside the base, and the holding end abuts against the clamping ring.

5. The partitioned soft light according to claim 1, wherein the plugging cylinder is provided with a limit groove, the holding sleeve is provided with a limit ring, and the limit ring is slidably arranged in the limit groove.

6. The partitioned soft light according to claim 1, wherein the sliding cylinder is provided with a blocking ring, and the holding sleeve is abutted against the blocking ring;

the first elastic piece is of a spring structure, one end of the first elastic piece is propped against the blocking ring, and the other end of the first elastic piece is propped against the base.

7. The zoned soft light of claim 6, wherein the base is provided with an anti-disengagement flange, and the blocking ring is abutted against the disengagement flange.

8. A method of assembling a zoned soft light of claim 2, comprising the steps of:

installing a plurality of LED lamp panels into the lampshade, wherein the LED lamp panels are distributed side by side;

attaching the radiator to the backlight surface of the LED lamp panel, wherein radiating fins of the radiator are in contact with the LED lamp panel; attaching a heat dissipating fan to a heat sink of the heat sink;

placing the controller into the lampshade, wherein a plurality of LED lamp panels are electrically connected with the controller;

the connection panel is electrically connected with the controller, the LED lamp panel and the cooling fan, and is fixedly arranged on the lamp shade to complete the lamp shade packaging;

and the regulation and control platform is connected with the controller in a wireless pairing mode.

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