CN215372336U - Lighting device with uniform light scattering lens - Google Patents

Abstract

The utility model provides a lighting device with a lens for uniformly scattering light rays, belongs to the technical field of lighting, and solves the problem of non-uniform light rays emitted through the lens in the prior art. The lighting device with the uniform light scattering lens comprises a lens frame, wherein the lens frame is connected with a radiator through a mounting frame, a plurality of lenses are arranged on the lens frame and sleeved on a luminous body, the lenses comprise light emergent faces for emitting light sources, the light emergent faces are of regular hexagonal structures, and adjacent edges between the lenses are mutually corresponding and arranged in parallel. The lighting device with the uniform light scattering lens is provided with the regular hexagonal lens, and light emitted by the lens is uniform.

Description

Lighting device with uniform light scattering lens

Technical Field

The utility model belongs to the technical field of illumination, and particularly relates to an illumination device with a uniform light scattering lens.

Background

With the development of LED technology, it is found that LEDs are one of the best illumination light sources at present, and have the advantages of high brightness, long service life, and the like. LEDs have been widely used as light sources for illumination lamps. With the improvement of living standard of people, some lighting fixtures for illumination are beginning to be used more and more in living, building, business and the like, and especially, a lighting fixture using an LED lamp as a light source is needed to save energy and prolong the service life of the lighting fixture.

The prior art discloses a combined lens for a light projecting lamp, which includes at least one circular mounting plate, two rows of central lenses are symmetrically arranged on the mounting plate along a center line passing through the diameter of the mounting plate, a gap is formed between two adjacent lenses of the central lenses, a plurality of rows of lenses decreasing in number in sequence are arranged on the central lenses in the direction far away from the center line, and the lenses in different rows on the same side of the center line are attached to the outer edges of two lenses in adjacent rows close to the center line. The above lens has the following disadvantages: the lens is in a circular shape, the lenses are arranged in a close contact manner and have gaps, because the lens is in a circular structure, the close contact parts between the two lenses are circular arcs, the distance between the two circular arcs is not completely equal, when the two lenses which are in close contact work, the lens is a circular divergent light source, the overlapping degree of the light source at the position with the closer distance between the two circular arcs is higher, the emitted light at the position is brighter, the overlapping degree of the light source at the position with the farther distance between the two circular arcs is lower, the emitted light at the position is darker relative to the former, and the light emitted through the lens becomes uneven due to different light and shade of each part.

SUMMERY OF THE UTILITY MODEL

In view of the above, the present invention provides a lighting device with a lens for scattering light uniformly, so as to solve the problem of non-uniform light emitted through the lens in the prior art.

The technical scheme adopted by the utility model is as follows:

the present invention provides an illumination device having a lens for uniformly scattering light, the illumination device comprising: the radiator is provided with a circuit board, and mounting frames are arranged on two sides of the radiator; the luminous body is arranged on the circuit board; the lens frame is connected with the radiator through the mounting frame, a plurality of lenses are arranged on the lens frame and sleeved on the luminous body, the lenses comprise light emitting surfaces used for emitting light sources, the light emitting surfaces are of regular hexagonal structures, and adjacent edges between every two adjacent lenses are mutually corresponding and arranged in parallel; the lampshade is arranged on the periphery of the lens frame and is connected with the radiator through the mounting frame.

As a preferable mode of the above-described lighting device having a lens for uniformly scattering light rays, the lens includes a total reflection surface which surrounds the light emitter.

As a preferable mode of the above lighting device having a lens for uniformly scattering light rays, the bottom of the total reflection surface has a regular hexagonal structure.

As a preferable embodiment of the above lighting device with a lens for uniformly scattering light rays, a circumference of the bottom of the total reflection surface is smaller than a circumference of the light exit surface.

In a preferred embodiment of the lighting device with the lens for uniformly scattering light, the lens holder is slidably connected to the heat sink, and the lamp cover is slidably connected to the heat sink.

As the preferable scheme of the lighting device with the uniform light scattering lens, a first sliding groove is formed in the mounting frame, a first protrusion is arranged on the lens frame, the lens frame passes through the first protrusion to slide in the first sliding groove, a second sliding groove is formed in the mounting frame, a second protrusion is arranged on the lamp cover, and the lamp cover passes through the second protrusion to slide in the second sliding groove.

As a preferable mode of the above-described lighting device having a lens for uniformly scattering light rays, the heat sink further includes a cover plate covering the side surfaces of the heat sink, the lens holder, and the lamp cover.

As a preferable scheme of the lighting device with the uniform light scattering lens, a threaded hole is formed in the mounting frame, and the cover plate is in threaded connection with the mounting frame through the threaded hole.

As a preferable mode of the above lighting device having a lens for uniformly scattering light rays, the cover plate is connected to the lamp housing through a first waterproof mechanism for preventing external water from entering the radiator and the inside of the lens.

As an optimal solution of the lighting device with the uniform light scattering lens, the first waterproof mechanism includes a first waterproof groove disposed on the lamp cover and a first waterproof protrusion disposed on the cover plate, and the first waterproof groove and the first waterproof protrusion cooperate to achieve waterproofing of the lamp cover.

In conclusion, the beneficial effects of the utility model are as follows:

the illumination device with the uniform light scattering lens provided by the embodiment of the utility model comprises a lens frame, wherein a plurality of lenses are arranged on the lens frame, the plurality of lenses comprise light emitting surfaces, the light emitting surfaces are of regular hexagonal structures, adjacent sides between every two adjacent lenses are mutually corresponding and arranged in parallel, the adjacent sides of the two regular hexagons are mutually corresponding and arranged in parallel, the distance between every two adjacent sides can be ensured to be equal, the overlapping degree of light sources at all positions is equal, and the distances between the adjacent lenses corresponding to the six sides of the regular hexagonal lenses and the lenses are equal, so that the light and shade of the light sources emitted by all the lenses are uniform.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required to be used in the embodiments of the present invention will be briefly described below, and for those skilled in the art, without any creative effort, other drawings may be obtained according to the drawings, and these drawings are all within the protection scope of the present invention.

FIG. 1 is a perspective view of a heat sink assembly of the present invention;

FIG. 2 is a view showing the internal structure of the heat dissipating module according to the present invention;

FIG. 3 is an enlarged view taken at point I of FIG. 2 according to the present invention;

FIG. 4 is a perspective view of the stand of the present invention;

FIG. 5 is an enlarged view taken at point II of FIG. 2 in accordance with the present invention;

FIG. 6 is a schematic structural view of a three-point positioning bracket according to the present invention;

FIG. 7 is a schematic structural view of a second adjustable fastener of the present invention;

FIG. 8 is an enlarged view taken at III of FIG. 2 in accordance with the present invention;

FIG. 9 is a schematic view of the heat sink assembly and the bracket according to the present invention;

FIG. 10 is a bottom view of the heat sink of the present invention;

FIG. 11 is a schematic view of a lens holder according to the present invention;

FIG. 12 is a front view of a lamp housing of the present invention;

FIG. 13 is a top view of a lamp enclosure of the present invention;

FIG. 14 is a schematic view of a lens configuration according to the present invention;

FIG. 15 is a front view of the cover plate of the present invention;

FIG. 16 is a side view of the cover plate of the present invention;

FIG. 17 is a schematic structural view of the housing of the present invention;

parts and numbering in the drawings:

1. a heat sink;

10. a heat dissipating component; 101. a heat conducting plate; 1011. a groove; 102. a heat sink; 1021. a first heat sink; 1022. a second heat sink; 1023. a third heat sink; 1024. a heat dissipation protrusion; 103. a first heat dissipation area; 104. a second heat dissipation area; 105. a first heat dissipation surface; 106. a second heat dissipation surface; 107. a thermal insulation region; 1071. a first heat insulation plate; 10711. a fourth chute; 1072. a second heat insulation plate; 1073. a power port; 108. a first mounting hole;

11. a housing; 111. a third protrusion; 112. a second contact portion; 113. a fourth protrusion;

12. a support; 121. a first fixing member; 1211. a fixed part; 12111. a third mounting hole; 1212. a bending part; 1213. a second connecting member; 122. a second fixing member; 1221. a second mounting hole; 1222. a guide groove;

13. a circuit board;

14. a mounting frame; 141. a first chute; 142. a second chute; 143. a threaded hole; 144. a third chute; 145. a first contact portion;

15. a cover plate; 151. a first waterproof projection;

3. a lens holder;

30. a lens; 31. a light-emitting surface; 32. a total reflection surface; 33. a first protrusion;

4. a lamp shade; 40. a second protrusion; 41. a first waterproof groove.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention. It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. In the description of the present invention, it is to be understood that the terms "center", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the referenced devices or elements must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, are not to be construed as limiting the present invention. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element. In case of conflict, the embodiments of the present invention and the various features of the embodiments may be combined with each other within the scope of the present invention.

Example one

Referring to fig. 1 to fig. 3, an embodiment of the utility model discloses a heat sink, including:

the heat dissipation component 10 comprises a heat conduction plate 101 and a plurality of heat dissipation fins 102, wherein the plurality of heat dissipation fins 102 are connected with the heat conduction plate 101, specifically, the bottoms of the plurality of heat dissipation fins 102 are connected with the heat conduction plate 101, a first heat dissipation area 103 and a second heat dissipation area 104 are formed in the heat dissipation component 10, the first heat dissipation area 103 and the second heat dissipation area 104 are respectively positioned in a left space and a right space, the height of the plurality of heat dissipation fins 102 in the first heat dissipation area 103 increases progressively in the vertical direction, the height of the plurality of heat dissipation fins 102 in the second heat dissipation area 104 decreases progressively in the vertical direction, at the position, the size of each heat dissipation fin 102 with the increasing or decreasing progressively in height does not need to be ensured to increase progressively or decrease progressively, only along the vertical direction, the height of the top of each heat dissipation fin 102 is different, through the arrangement mode, a first heat dissipation surface 105 is formed on each heat dissipation fin 102, and the first heat dissipation surface 105 is an area where the previous heat dissipation fin 102 cannot be projected on the next heat dissipation fin 102, on the first heat radiation surface 105, the heat of the previous heat radiation fin 102 does not affect the heat exchange process between the first heat radiation surface 105 and the cold air, and the heat radiation efficiency of the first heat radiation surface 105, which is an area that cannot be projected, is higher than that of the projection surface. It is understood that in the first heat dissipation area 103 or the second heat dissipation area 104, the left side of the heat sink 102 at the first row has no heat sink 102, and the right side of the heat sink 102 at the end of the row has no heat sink 102, so that the left side or the right side of the heat sink 102 is in direct contact with the outside air and is not affected by the heat of the adjacent heat sink 102, and thus, the left side or the right side is also the first heat dissipation surface 105 in practice. In addition, at least two first mounting holes 108 are formed in the heat dissipation assembly 10, the first mounting holes 108 are used for mounting the following support 12, and the number of the first mounting holes 108 is two, so that two-point positioning can be realized, and the rotating position of the heat dissipation assembly 10 can be effectively limited; the number of the first mounting holes 108 is three, so that three-point positioning can be realized, and the fixing effect is better.

A housing 11, please refer to fig. 2 and 7, wherein the housing 11 is slidably connected with the heat dissipation assembly 10 through a second waterproof mechanism, the housing 11 is substantially slidably connected with a mounting rack 14 on the following heat dissipation assembly 10, the sliding connection facilitates the mounting and dismounting of the housing 11, the second waterproof mechanism has a better waterproof effect, and the second waterproof effect has both a guiding function and a waterproof function through the sliding connection of the second waterproof mechanism, and the radiator adopting the structure is convenient to mount and dismount and has good waterproof performance;

referring to fig. 1 and 4, the bracket 12 is connected to the heat dissipating assembly 10 through the first mounting hole 108, the bracket 12 includes a first fixing member 121 and two second fixing members 122, the two second fixing members 122 are disposed on two sides of the first fixing member 121, the second fixing member 122 is provided with a second mounting hole 1221 and a guide groove 1222, and the second mounting hole 1221 and the guide groove 1222 are connected to the first mounting hole 108 through a first connecting member. Specifically, second mounting hole 1221 is the installation basic point, and radiator 1 can rotate around second mounting hole 1221, and after radiator 1 rotated certain angle, the guide way 1222 and first mounting hole 108 are connected to first connecting piece, realized the multiple spot location, and fixed more firm between radiator 1 and support 12 can effectively prevent that radiator 1 fixed angle from producing the skew. Further, the second mounting hole 1221 is a circular hole, and the first connecting member may be a bolt.

The mounting frames 14, please refer to fig. 2 and 8, are disposed on two sides of the heat dissipation assembly 10 along the first direction;

referring to fig. 15 and 16, after the housing 11 is connected to the heat dissipation assembly 10, the cover plate 15 covers both sides of the heat dissipation assembly 10 and the housing 11 along a second direction perpendicular to the first direction through a third waterproof mechanism, when in specific use, the housing 11 slides into the heat dissipation assembly 10 through the second waterproof mechanism until the sides of the heat dissipation assembly 10 and the housing 11 along the second direction are overlapped, the third waterproof mechanism covers the sides of the heat dissipation assembly 10 and the housing 11, the sides of the heat dissipation assembly 10 and the housing 11 along the second direction are both two, and are located at two opposite ends of the second direction, and correspondingly, the number of the third waterproof mechanisms is also two.

To facilitate understanding of the structure of the heat sink 1, the structures of the heat dissipating assembly 10, the bracket 12, the second waterproof mechanism, and the third waterproof mechanism will now be further described as follows:

referring to fig. 2, 3 and 5, the heat sink 102 includes first heat sinks 1021 and second heat sinks 1022, the first heat sinks 1021 and the second heat sinks 1022 are alternately disposed on the heat conducting plate 101, the bottom of the second heat sinks 1022 is disposed with second heat dissipating surfaces 106, the functions of the second heat dissipating surfaces 106 are similar to those of the first heat dissipating surfaces 105, both of which are to avoid thermal interference between adjacent heat sinks 102, and the second heat dissipating surfaces 106 are non-projectable areas of the adjacent first heat sinks 1021 on the second heat dissipating surfaces 106, i.e. non-projectable areas of the first heat sinks 1021, so that in the areas of the second heat dissipating surfaces 106, the heat of the adjacent first heat sinks 1021 does not affect the heat dissipating effect of the second heat sinks 1022.

Further, the heat conducting plate 101 is provided with a plurality of grooves 1011, the second heat dissipating fins 1022 are disposed in the middle of the grooves 1011, and the second heat dissipating surfaces 106 are projection surfaces of inner walls of the grooves 1011 on the second heat dissipating fins 1022, in this case, two second heat dissipating surfaces 106 are disposed on two sides of the second heat dissipating surfaces 106, respectively, the inner walls of the grooves 1011 are two, and the projection surfaces of the inner walls of the two grooves 1011 on the second heat dissipating fins 1022 are the second heat dissipating surfaces 106.

Preferably, referring to fig. 3, the heat sink 102 is provided with heat dissipating protrusions 1024, the heat dissipating protrusions 1024 can increase the surface area of the heat sink 102, the larger the surface area of the heat sink 102 is, the more the portion in contact with the outside air is, the more the heat quantity is alternately heated and cooled by the outside air, and the better the heat dissipating effect of the heat sink 102 is. Specifically, the heat dissipation protrusions 1024 are of a sawtooth structure, the sawtooth structure is convenient to process, the contact area with the outside air is large, and in an optimal mode, it can be understood that the heat dissipation protrusions 1024 may also be of a circular arc shape, a rectangular shape or other shapes protruding outwards, and examples are omitted here.

Referring to fig. 2, the heat dissipation assembly 10 further includes a thermal insulation region 107, the thermal insulation region 107 is disposed between the first heat dissipation region 103 and the second heat dissipation region 104, and the power line of the heat sink 1 extends to the outside of the housing 11 through the thermal insulation region 107. In this thermal insulation region 107, the heat is less, and the power cord passes this region and can not receive the influence, if do not set up thermal insulation region 107, the power cord directly wears out from the heat dissipation region, and the heat that the heat dissipation region gived off can soften the power cord, and more serious can damage the power cord.

Further, heat-insulating area 107 includes first heat insulating board 1071, second heat insulating board 1072 and power port 1073, and first heat insulating board 1071, second heat insulating board 1072 and power port 1073 all set up on heat-conducting plate 101, and power port 1073 sets up between first heat insulating board 1071 and second heat insulating board 1072, and the power cord draws out the outside of radiator 1 shell 11 from power port 1073 through heat-insulating area 107, and the heat in the radiator 1 basically can not influence the power cord. Further, the heat dissipation plate 102 further includes third heat dissipation plates 1023, the third heat dissipation plates 1023 are disposed at both sides of the first heat insulation plate 1071 and the second heat insulation plate 1072, and the height of the third heat dissipation plates is lower than that of the first heat insulation plate 1071 and the second heat insulation plate 1072, so that the internal space of the heat sink 1 can be fully utilized, and the power cord is not affected.

Referring to fig. 1, the heat sink 102 is a plate-shaped structure, which has a larger surface area and better heat dissipation effect.

As a preferable embodiment of the heat sink, referring to fig. 1 and 4, the two guide slots 1222 are arc-shaped and are disposed at both sides of the second mounting hole 1221, the two first mounting holes 108 are connected to the second mounting hole 1221 and one of the guide slots 1222 by the first connecting member, and the two guide slots 1222 are used for adjusting a wider mounting angle. In this embodiment, the two first mounting holes 108 are respectively connected to the second mounting hole 1221 and one of the guide slots 1222, so that two-point positioning can be achieved, and relative rotation between the heat sink 1 and the bracket 12 can be effectively prevented, thereby preventing the fixed position of the heat sink 1 and the light projection angle on the heat sink 1 from being shifted.

As a preferable embodiment of the heat sink, referring to fig. 1 and 6, the guide slot 1222 is a circular hole, the number of the first mounting holes 108 is three, the three first mounting holes 108 are respectively connected with the second mounting hole 1221 and the guide slot 1222 through first connectors, the three first connectors are connected into a line to form three-point positioning, and the rotation angle of the heat sink 1 can be increased to 360 °, which not only has good fixing effect, but also has a wide application range.

Referring to fig. 5, further, the first fixing element 121 includes a fixing portion 1211 and two bending portions 1212, and the two bending portions 1212 are disposed at two ends of the fixing portion 1211, so that the length of the fixing portion 1211 is smaller than the distance between the two second fixing elements 122, and the bracket 12 can be fixed in a relatively narrow place. Further, the fixing portion 1211 is provided with a third mounting hole 12111, the third mounting hole 12111 may fix the bracket 12 at a predetermined position, and the third mounting hole 12111 may be a screw.

As a preferable scheme of the heat sink, referring to fig. 2, 7 and 8, the first fixing element 121 has an adjustable structure, the first fixing element 121 includes a plurality of second connecting elements 1213, the angle between the plurality of second connecting elements 1213 is adjustable, the second connecting elements 1213 are connected to the second fixing element 122, and the angle between the second connecting elements 1213 and the second fixing element 122 is adjustable. Because the angles between the second connecting members 1213 and the second fixing members 122 are adjustable, the inclination angle of the first fixing member 121 can be adjusted, and when facing walls with different included angles, the first fixing members 121 with different inclination angles can be attached to two walls. Further, the first fixing member 121 is provided with a screw hole 143, and when the first fixing member 121 is adjusted to a preset position, the first fixing member 121 and the wall are fixed through the screw hole 143. Furthermore, the second connecting members 1213 are arranged in pairs, and the included angle range of the second connecting members 1213 arranged in pairs is larger, so that the method can be applied to more scenes.

Further, two adjacent second connecting members 1213 are connected by bolts, and the second connecting members 1213 are connected to the second fixing member 122 by bolts. Specifically, through holes are formed in the second connecting member 1213 and the second fixing member 122, the rod passes through the two second connecting members 1213 or the second connecting member 1213 and the second fixing member 122 to fix the positions of the two second connecting members 1213 or the second connecting members 1213 and the second fixing member 122, a nut is connected to one end of the screw, and when the second connecting member 1213 and the second fixing member 122 reach a preset position, the screw and the nut are used for fixing. Further, adjacent two second connecting members 1213 are connected by a preload member bolt, and the second connecting members 1213 are connected to the second fixing member 122 by the preload member bolt. The pretensioning piece can select the spring for use, and can make bolted connection more stable.

Referring to fig. 2, 8 and 17, the second waterproof mechanism includes a guiding mechanism and a protecting mechanism, the housing 11 is slidably connected to the heat dissipating assembly 10 through the guiding mechanism, the guiding direction of the guiding mechanism is a first direction, the guiding direction conforms to the heat dissipating fins of the heat sink, the housing 11 slides along the guiding direction of the guiding mechanism, and the guiding mechanism has a waterproof function, so as to effectively prevent external water from entering the heat sink; the protection mechanism is used for preventing external water from entering the guide mechanism, the protection mechanism serves as a first mechanism for isolating the external water, most of the external water can be blocked outside the shell 11, even if water seepage occurs, only a small amount of water enters the guide mechanism, the waterproof effect of the guide mechanism is excellent, and the protection mechanism and the guide mechanism are matched to effectively prevent the external water from entering the radiator.

Further, guiding mechanism includes third spout 144 and third arch 111, and third spout 144 sets up on mounting bracket 14, and third arch 111 sets up on shell 11, and third spout 144 realizes shell 11 and radiator unit 10 sliding connection with the protruding 111 cooperation of third, and the area of contact of shell 11 with radiator unit 10 has been increased in the setting of third spout 144, and water-proof effects is better, and the spout matches with protruding and compares that the plane matches can be tighter with the plane, and water-proof effects is better. Furthermore, an opening (not shown) is formed in the third sliding groove 144, the maximum width of the cross section is larger than the width of the opening in the cross section perpendicular to the guiding direction of the guiding mechanism, the opening is a portion of the sliding groove contacting with the external environment, because the third protrusion 111 is adapted to the third sliding groove 144, a protrusion portion (not shown) with a larger width and a connecting portion (not shown) with a smaller width are also formed on the third protrusion 111, the protrusion portion is matched with the inside of the sliding groove, the connecting portion penetrates through the opening and extends out of the third sliding groove 144, and because the maximum width of the cross section is larger than the width of the opening, the protrusion portion of the third protrusion 111 can be clamped in the sliding groove and cannot slide out of the opening, so that the supporting and fixing effects are good. Further, the convex portion of the third protrusion 111 may be circular, rectangular or other shapes, and it is only necessary to ensure that the maximum width of the convex portion is greater than the width of the connecting portion, and the specific shape of the third protrusion 111 is not limited herein.

Referring to fig. 2, 8 and 17, the shielding mechanism includes a first contact portion 145 and a second contact portion 112, the first contact portion 145 is disposed on the mounting frame 14, the second contact portion 112 is disposed on the housing 11, the second contact portion 112 covers the first contact portion 145, the first contact portion 145 and the second contact portion 112 have a certain length, and the second contact portion 112 covers the first contact portion 145, so that the contact area between the housing 11 and the heat dissipation assembly 10 is increased, and most of external water can be prevented from entering the guiding mechanism. Further, the first contact portion 145 and the second contact portion 112 are obliquely arranged, the oblique arrangement substantially has a certain bending of the mounting frame 14, and after the fixed angle of the heat sink is adjusted by the bracket, the heat sink also has a certain oblique angle, and the oblique arrangement has the bending portion such that the first contact portion 145 and the second contact portion 112 are located above the mounting frame 14, and external water is difficult to permeate into the heat sink.

Referring to fig. 16 and 17, the third waterproof mechanism includes a second waterproof protrusion (not shown) and a second waterproof groove (not shown), the second waterproof protrusion is disposed on the cover plate 15, the second waterproof groove is disposed on the housing 11, and the second waterproof protrusion and the second waterproof groove cooperate to achieve the sealing and waterproof functions of the heat sink. Further, the waterproof protruding outer lane setting along apron 15 of second, the waterproof recess of second sets up along the outer lane of shell 11, and water-proof effects is better. Furthermore, sealing rubber is arranged between the second waterproof protrusion and the second waterproof groove, so that the waterproof effect is better.

Referring to fig. 2 and 17, a first heat insulation plate 1071 and a second heat insulation plate 1072 are disposed on the heat dissipation assembly 10, fourth sliding grooves 10711 are disposed on the first heat insulation plate 1071 and the second heat insulation plate 1072, the fourth sliding grooves 10711 are disposed along the second direction, a fourth protrusion 113 is disposed on the housing 11, and the fourth sliding grooves 10711 and the fourth protrusion 113 are matched to support and position the housing 11. Furthermore, a wire outlet (not shown) is formed in the housing 11, a power line of the radiator is led out of the housing 11 from the heat dissipation assembly 10 through the wire outlet, a soft sleeve (not shown) is arranged on the housing 11, the soft sleeve penetrates through the wire outlet, sealing rings (not shown) are integrally arranged at two opposite ends of the soft sleeve, the sealing rings are respectively attached to the inner wall and the outer wall of the housing 11, the soft sleeve has certain elasticity, the power line penetrates through the soft sleeve, and the elasticity of the soft sleeve acts on the power line to realize sealing and prevent external water from entering the radiator from a connection part of the soft sleeve and the power line.

Example two

Referring to fig. 9 to 13, the present invention provides an illumination device, including:

in the heat sink 1, the heat sink 1 is used for dissipating heat of the lighting device, the circuit board 13 is arranged on the heat sink 1, the circuit board 13 provides lighting conditions for the light emitting body, and the mounting frames 14 are arranged on two sides of the heat sink 1.

And the luminous body (not shown) is arranged on the circuit board 13, and the luminous body emits light rays after the circuit board 13 is electrified.

The lens frame 3, the lens frame 3 is connected with the heat sink 1 through the mounting frame 14, a plurality of lenses 30 are arranged on the lens frame 3, the plurality of lenses 30 are sleeved on the light emitter, the positions of the lenses 30 correspond to the positions of the light emitter to project uniform light, the plurality of lenses 30 comprise a light emitting surface 31 used for emitting light sources, the light emitting surface 31 is of a regular hexagon structure, adjacent sides between two adjacent lenses 30 correspond to each other and are arranged in parallel, the adjacent sides of the two regular hexagons correspond to each other and are arranged in parallel to ensure that the distances between the two adjacent sides are equal everywhere on each adjacent side, the light source overlapping degrees at all positions are equal, and the distances between the adjacent lenses 30 corresponding to the six sides of the regular hexagon lenses 30 and the lenses 30 are equal, so that the light sources of all the lenses 30 are uniform in shade and uniform in emission.

The lampshade 4 is arranged on the periphery of the lens frame 3 and used for preventing water and dust, and the lampshade 4 is connected with the radiator 1 through the mounting frame 14.

To facilitate understanding of the structure of the lighting device, the structure of the lens 30 and the heat sink 1 will now be further described as follows:

referring to fig. 14, the lens 30 includes a total reflection surface 32, the total reflection surface 32 surrounds the light emitter, and the light emitted from the light emitter is reflected by the total reflection surface 32 and exits the lens 30. The bottom of the total reflection surface 32 is in a regular hexagon structure, the total reflection surface 32 surrounds the light emitter, and the light reflected by the lens 30 is more uniform due to the regular hexagon shape. The circumference of the bottom of the total reflection surface 32 is smaller than the circumference of the light emitting surface 31, so that an inverted hexagonal frustum structure is formed inside the lens 30, and light emitted by the light emitting body can be better reflected.

Referring to fig. 2, 8 and 11, the lens holder 3 is slidably connected to the heat sink 1, and the lamp housing 4 is slidably connected to the heat sink 1. Be provided with first spout 141 on the mounting bracket 14, be provided with first arch 33 on the lens holder 3, lens holder 3 slides in first spout 141 through first arch 33, be provided with second spout 142 on the mounting bracket 14, be provided with the protruding 40 of second on the lamp shade 4, lamp shade 4 slides in second spout 142 through the protruding 40 of second, first spout 141 and the setting of second spout 142 along mounting bracket 14 length direction on the mounting bracket 14, the protruding entering that can effectively prevent outside water and outside dust with the cooperation of spout.

Further, the heat sink 1 further includes a cover plate 15, and the cover plate 15 covers the side surfaces of the heat sink 1, the lens holder 3, and the lamp housing 4. The cover plate 15 can fix the lens holder 3 and the globe 4 to prevent them from sliding in the slide grooves. Further, a threaded hole 143 is formed in the mounting frame 14, and the cover plate 15 is in threaded connection with the mounting frame 14 through the threaded hole 143.

Referring to fig. 12, 13, 15 and 16, the cover plate 15 is connected to the lamp housing 4 by a first waterproof mechanism for preventing external water from entering the heat sink 1 and the lens 30. Specifically, the first waterproof mechanism includes a first waterproof groove 41 disposed on the lamp shade 4 and a first waterproof protrusion 151 disposed on the cover plate 15, and the first waterproof groove 41 and the first waterproof protrusion 151 cooperate to achieve waterproofing of the lamp shade 4.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the utility model has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.

Claims (10)

1. A lighting device having a lens for uniformly diffusing light, said lighting device comprising:

the radiator is provided with a circuit board, and mounting frames are arranged on two sides of the radiator;

the luminous body is arranged on the circuit board;

the lens frame is connected with the radiator through the mounting frame, a plurality of lenses are arranged on the lens frame and sleeved on the luminous body, the lenses comprise light emitting surfaces used for emitting light sources, the light emitting surfaces are of regular hexagonal structures, and adjacent edges between every two adjacent lenses are mutually corresponding and arranged in parallel;

the lampshade is arranged on the periphery of the lens frame and is connected with the radiator through the mounting frame.

2. The illumination device as recited in claim 1, wherein the lens comprises a total reflection surface surrounding the illuminator.

3. The illumination device as claimed in claim 2, wherein the bottom of the total reflection surface has a regular hexagonal structure.

4. The illumination device as recited in claim 3, wherein the perimeter of the bottom of the total reflection surface is smaller than the perimeter of the light exit surface.

5. The lighting device with a lens for evenly scattering light as claimed in claim 1, wherein the lens holder is slidably connected to the heat sink, and the lamp cover is slidably connected to the heat sink.

6. The lighting device with the lens for evenly scattering light according to claim 5, wherein a first sliding groove is formed on the mounting frame, a first protrusion is formed on the lens frame, the lens frame slides in the first sliding groove through the first protrusion, a second sliding groove is formed on the mounting frame, a second protrusion is formed on the lamp cover, and the lamp cover slides in the second sliding groove through the second protrusion.

7. The lighting device with a uniform light scattering lens as claimed in claim 6, wherein the heat sink further comprises a cover plate covering the sides of the heat sink, the lens holder and the lamp housing.

8. The lighting device with the lens for evenly scattering light rays as claimed in claim 7, wherein the mounting frame is provided with a threaded hole, and the cover plate is in threaded connection with the mounting frame through the threaded hole.

9. The lighting device with a lens for evenly scattering light rays as claimed in claim 7, wherein the cover plate is connected to the lamp housing by a first waterproof mechanism for preventing external water from entering the inside of the lens and the heat sink.

10. The lighting device with the lens for uniformly scattering light rays as claimed in claim 9, wherein the first waterproof mechanism comprises a first waterproof groove disposed on the lampshade and a first waterproof protrusion disposed on the cover plate, and the first waterproof groove and the first waterproof protrusion cooperate to waterproof the lampshade.

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