High heat dissipation LED industrial and mining lamp
Technical Field
The utility model relates to a LED lighting technology field specifically is a high heat dissipation LED industrial and mining lamp.
Background
The industrial and mining lamp is widely applied to illumination of large-scale venues such as garages, factory buildings, gymnasiums and the like. The requirement on brightness is high, the temperature of the lamp is increased, and the existing industrial and mining lamp is large in size and inconvenient to transport and install in order to solve the problems of brightness and heat dissipation.
SUMMERY OF THE UTILITY MODEL
An object of the utility model is to provide a high heat dissipation LED industrial and mining lamp, it is small, light in weight, and the heat dissipation is fast.
The utility model adopts the technical proposal that: a high-heat-dissipation LED mining lamp comprises an integrally-formed radiator, a light-emitting assembly, a rear cover plate and a power supply, wherein the light-emitting assembly is arranged on the front surface of the radiator; the radiating ribs are radially distributed around the circumference of the disc for a circle, and a circular cavity is formed inside the back of the disc.
In the high-heat-dissipation LED mining lamp, a plurality of heat dissipation fins are arranged in the circular cavity, and the height of each heat dissipation fin is lower than the plane where the top end of each heat dissipation rib is located.
In the high-heat-dissipation LED mining lamp, the disc is provided with four pot cavities which protrude towards the back of the disc, and one end of the disc extends into the circular cavity to form a ventilation duct; the heat dissipation ribs on the same circumference are divided into four parts with the same size by the basin cavity; the inner side surface of the pelvic cavity is provided with a connecting column, the upper end of the connecting column is provided with a first preset hole, and the rear cover plate is provided with a second preset hole corresponding to the connecting column.
In the high-heat-dissipation LED mining lamp, the front surface of the disc is provided with the plurality of reinforcing ribs which are radially arranged and are on the same circumference with the heat dissipation ribs.
In the above high heat dissipation LED mining lamp, the light emitting assembly includes a lamp shade and a light source plate; the middle part of the lampshade is provided with a lens module corresponding to the light source plate, the periphery of the lampshade is divided into four regions with the same size, the four regions correspond to the cavity chamber one by one, and a plurality of first heat dissipation holes are formed in the periphery of the lampshade; the light source plate is detachably fixed in the area where the round cavity in the front of the radiator is located.
In the high-heat-dissipation LED mining lamp, a plurality of second heat dissipation holes are distributed in the region where the circular cavity in the middle of the heat radiator is located.
In the high-heat-dissipation LED mining lamp, a square groove is formed in the middle of the radiator, the bottom of the square groove is provided with an opening, and a radar sensor is distributed in the square groove; the power supply is placed above the radar sensor.
In the high-heat-dissipation LED mining lamp, a power supply hole is formed in the joint of the back surface of the radiator and the light source plate.
In the high-heat-dissipation LED mining lamp, the rear cover plate is provided with a lifting hook and a wire hole.
Compared with the prior art, the beneficial effects of the utility model are that: the heat dissipation ribs arranged on the radiator are connected with the rear cover plate, and a cavity is formed in the radiator, so that the heat dissipation effect is better; spaces are reserved among the radiating ribs on the radiator, and first radiating holes are formed in the corresponding area of the basin cavity on the lamp panel to form convection radiating so as to further improve the radiating effect; the inside radar sensor that is equipped with of industrial and mining lamp can be according to the illumination intensity automatic control lighting apparatus of environment, and the power saving is practiced thrift to the intelligence.
Drawings
Fig. 1 is a top exploded view of the mining lamp of the present invention;
fig. 2 is a bottom exploded view of the mining lamp of the present invention;
fig. 3 is a back structural view of the heat sink of the present invention;
fig. 4 is an overall structure diagram of the mining lamp of the utility model;
in the drawings are labeled: 1-hook, 2-back cover plate, 3-second preset hole, 4-radar sensor, 5-radiator, 6-radiating rib, 7-lampshade, 8-lens module, 9-first radiating hole, 10-power supply, 11-light source plate, 12-reinforcing rib, 13-second radiating hole, 14-first preset hole, 15-pelvic cavity, 16-radiating fin, 17-connecting column, 18-square groove and 19-power supply hole.
Detailed Description
The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.
Example (b): as shown in fig. 1-4, a high heat dissipation LED mining lamp comprises an integrally formed heat sink 5, a light emitting assembly disposed on the front side of the heat sink 5, a rear cover plate 2 connected to the back side of the heat sink 5, and a power supply 10 disposed inside the heat sink 5, wherein the heat sink 5 is composed of a disk and a plurality of heat dissipation ribs 6 with the same size integrally formed on the back side of the disk, and a space is provided between two adjacent heat dissipation ribs 6; the radiating ribs 6 are radially distributed around the circumference of the disc for one circle, and a circular cavity is formed inside the back of the disc.
A circle of radiating ribs 6 are distributed on the circumference of the disc, so that a circular cavity is formed in the disc, the space between the rear cover plate 2 and the radiator 5 is enlarged, and the heat radiation is faster; all be equipped with the interval between two adjacent heat dissipation muscle 6, the heat spreads outside the lamp body from the interval for the heat dissipation.
In this embodiment, a plurality of heat dissipation fins 16 are disposed in the circular cavity, and the height of the heat dissipation fins 16 is lower than the plane where the top ends of the heat dissipation ribs 6 are located.
The design of the heat dissipation fins 16 not only enhances the overall strength of the heat sink 5, but also effectively increases the heat dissipation area, thereby accelerating heat dissipation.
In this embodiment, the disc is provided with four pot cavities 15 protruding to the back of the disc, and one end of each pot cavity extends into the circular cavity to form an air duct; the heat dissipation ribs 6 on the same circumference are divided into four parts with the same size by the basin cavity 15; the inner side surface of the cavity 15 is provided with a connecting column 17, the upper end of the connecting column 17 is provided with a first preset hole 14, and the rear cover plate 2 is provided with a second preset hole 3 corresponding to the connecting column 17.
The design of the pelvic cavity 15 increases heat dissipation channels, thereby effectively accelerating heat dissipation; the design of spliced pole 17, back shroud 2 and radiator 5 are connected, and available bolt is connected the first preset hole 14 on spliced pole 17 and the second on the back shroud 2 predetermines hole 3, dismantles easy maintenance.
In this embodiment, the front surface of the disk is provided with a plurality of reinforcing ribs 12 which are radially arranged and are on the same circumference with the heat dissipation ribs 6.
The design of the reinforcing ribs 12 is used for increasing the overall strength of the disc, and the structure is safer and more reliable.
In this embodiment, the light emitting assembly includes a lamp housing 7 and a light source plate 11; the middle part of the lampshade 7 is provided with a lens module 8 corresponding to the light source plate 11, the periphery of the lampshade 7 is divided into four areas with the same size, the four areas correspond to the cavity 15 one by one, and a plurality of first heat dissipation holes 9 are arranged on the periphery of the lampshade; the light source plate 11 is detachably fixed in the area of the circular cavity on the front surface of the heat sink 5.
The light source plates 11 correspond to the lens modules 8 one by one, and the lens modules 8 are used for preventing foreign objects from damaging the light source plates 11 and ensuring that the light source plates 11 can normally illuminate; the lampshade 7 is detachably connected with the front side of the radiator 5, the periphery of the lampshade 7 is divided into four areas, each area corresponds to one cavity 15, and each area is provided with a plurality of first radiating holes 9, so that radiating convection channels are formed in the front and the back of the LED mining lamp, and the radiating effect is good; the light source plate 11 is fixed on the radiator 5 through bolts, and is stable in structure and convenient to detach and maintain.
In this embodiment, a plurality of second heat dissipation holes 13 are distributed in the region where the circular cavity is located in the middle of the heat sink 5.
The design of the second heat dissipation hole 13 can increase the heat dissipation channel, further speeding up the heat dissipation.
In this embodiment, a square groove 18 is arranged in the middle of the heat sink 5, the bottom of the square groove 18 is open, and the radar sensor 4 is arranged in the square groove 18; the power supply 10 is placed above the radar sensor 4.
The radar sensor 4 is not influenced by environment, temperature, dust and the like, can penetrate through non-metallic substances to detect the motion of an object, and automatically controls the lighting equipment according to the illumination intensity of the environment, so that the brightness of the lamp is adjusted, and the lamp is strong in anti-interference performance, high in sensitivity, strong in reliability, safe, convenient and intelligent and saves electricity.
In this embodiment, a power supply hole 19 is formed at the connection between the back surface of the heat sink 5 and the light source board 11.
The light source board 11 can be directly connected with the power supply 10 through the power supply hole 19, which is convenient and safe.
In this embodiment, the rear cover plate 2 is provided with a hook 1 and a wire hole.
The design of lifting hook 1 is convenient for the installation of industrial and mining lamp and is placed, and this lifting hook 1 can 360 degrees rotations on the coplanar.
It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.