CN201133628Y - High Power LED Explosion Proof Light - Google Patents

Abstract

A high-power LED explosion-proof lamp, its structure includes a casing, a light-emitting component, and a heat sink; the light-emitting component includes a reflective bowl, an LED bulb, and a lens. The outer end is docked with the inner wall of the shell, and the inner end is connected with the outer wall of an annular cylinder. The front faces of all the heat sinks form a conical concave annular surface, and the reflective bowl is set on the annular surface; the annular cylinder The axis coincides with the axis of the housing, and the front end of the annular cylinder is plane-shaped, and the LED bulb and the lens are installed on the plane. Compared with the existing technology, the front-to-back communication and radiating fence-like heat sinks are set in the shell, which is more conducive to the air flowing around the heat sinks in front, back, left, and right, as well as the transfer of heat, and timely removes the heat generated by the LED nodes, improving heat dissipation Effect.

Description

High Power LED Explosion Proof Light

technical field

The utility model relates to a high-power LED explosion-proof lamp, in particular to a heat dissipation structure of the high-power LED explosion-proof lamp.

Background technique

In recent years, LED lights have become more and more favored by the society because of their low power consumption, long service life, energy saving and environmental protection. Therefore, they have developed extremely rapidly. The structure of the existing LED lamp is generally composed of a lamp housing, a lamp holder, a reflective bowl, and a light bulb, a lens, a driving power supply, etc. In order to prevent the excessive heat of the nodes of the LED lamp (light-emitting diode lamp) from affecting the service life of the bulb, the lamp housing There are generally different forms of heat sinks on the top. For low-power LED lamps, because of their low power consumption, they generate little heat and do not need to be equipped with special cooling parts, but for high-power LED explosion-proof lamps, especially those that require continuous lighting. , heat dissipation components are still essential. The setting method and structure of the existing heat dissipation parts are generally to arrange sheet-like heat sinks around the light bulb at the rear of the reflective bowl or to open heat dissipation holes on the shell wall, so as to dissipate the heat generated by the nodes in time and ensure the light normal work.

Chinese Patent No. 2005201343984, a "heat dissipation assembly structure for high-power LED lamps", has made a good attempt on the heat dissipation problem. Its structure includes a base, light-emitting components, switching power supply components, etc. The rear of the base cavity is equipped with a switching power supply component. The switching power supply component includes an inner ring, and the front of the base cavity is embedded with a light-emitting component. , High-power LED bulbs, lenses, and heat sinks are embedded in the inner ring. This is a relatively typical heat dissipation structure, which adopts several technical means: first, a fastening cover ring is pressed between the front port periphery of the stepped engagement base of the reflective bowl, and the internal thread of the fastening cover ring is connected with the The external thread of the front port of the base is tightly pressed on the inner side of the heat sink, which is used to compress the reflective bowl to achieve a good heat dissipation effect. The second is a heat dissipation lamp holder. There are two lugs in the center hole of the heat dissipation lamp holder to install the lamp head through screws. There are special heat dissipation chips inside the heat dissipation lamp holder.

It can be seen that the heat dissipation structure of the above type has the following disadvantages in practical application:

One is that the heat sink is set inside the front port of the base (that is, the front port of the shell), and the air cannot flow in multiple directions around the heat sink, which affects the heat dissipation effect; the other is that it is necessary to install a heat dissipation lamp holder, and a special heat dissipation lamp holder needs to be installed inside the heat dissipation lamp holder. The heat dissipation chip not only has a complicated structure, but also increases the production cost.

Contents of the invention

In order to overcome the above-mentioned deficiencies in the prior art, the utility model aims to provide a high-power LED explosion-proof lamp with a new structure, which has the ability of air to flow around the heat sink in multiple directions, front, back, left, and right, and does not need to install a special heat dissipation chip. Therefore, not only is the structure simple, but also has a particularly good heat dissipation effect.

In order to achieve the above object, the utility model adopts the following technical solutions:

The structure of this high-power LED explosion-proof lamp includes: a housing, a light-emitting component, and a heat sink; the light-emitting component includes a reflective bowl, an LED bulb, and a lens. The outer end is docked with the inner wall of the shell, and the inner end is connected with the outer wall of an annular cylinder. The front faces of all the heat sinks form a conical concave annular surface, and the reflective bowl is set on the annular surface; the annular cylinder The axis coincides with the axis of the casing, and the front end of the annular cylinder is plane-shaped, and the LED bulb and the lens are installed on the plane.

The above-mentioned high-power LED explosion-proof lamp, the drive power supply is installed in the ring-shaped cylinder body, the front end of the ring-shaped cylinder body has a lens compression cover, the rear part is provided with a rear end cover, and the lens is installed on the front surface of the ring-shaped cylinder body and The lens is pressed between the caps.

The above-mentioned high-power LED explosion-proof lamp has a casing, a heat sink, an annular cylinder and a reflective bowl as an integral part.

In the above-mentioned high-power LED explosion-proof lamp, the areas other than the inner and outer rings of the reflective bowl are distributed with cooling channels formed by fence-shaped cooling fins.

In the above-mentioned high-power LED explosion-proof lamp, the lens pressing cover, the annular cylinder and the rear end cover are connected by connecting bolts to form a sealed whole.

The high-power LED explosion-proof lamp described above has a cylindrical shell.

The high-power LED explosion-proof lamp described above has a polygonal shell.

The above-mentioned high-power LED explosion-proof lamp is provided with a positioning bracket on the shell.

The above-mentioned high-power LED explosion-proof lamp is provided with cooling through holes on the shell.

Beneficial effects: Compared with the prior art, a heat sink in the shape of a radiation fence is arranged in the casing, and an LED light source and a lens are arranged in the middle of the front end of the casing, and a reflective bowl is arranged on the conical concave ring surface around the lens , so that it forms a lamp similar to a fan structure, and the shell, heat sink, annular cylinder and reflective bowl are connected as a whole, which is more conducive to the air flow around the heat sink, front and back, left and right, and heat transfer, and timely eliminate LED The heat generated by the nodes improves the heat dissipation effect, thereby solving the problem that the reflective bowl (or reflective plate, reflective ring, etc.) in the prior art blocks the front and back of the lamp, causing the air to not circulate back and forth. In addition, the lens compression cover, the annular cylinder and the rear end cover are connected together by bolts, which is not only easy to disassemble, but also particularly conducive to heat dissipation. Furthermore, because the utility model omits the special cooling chip, the structure becomes simpler and the production cost is reduced.

In order to further understand the content of the utility model, the following will be described in detail in conjunction with the accompanying drawings through the embodiments

Description of drawings

Figure 1 is a schematic diagram of the main view structure;

Fig. 2 is a schematic view of the structure in the bottom view of Fig. 1, and the support structure is not shown in the figure;

FIG. 3 is a schematic diagram of the exploded structure of the components in FIG. 1 , and the bracket structure is not shown in the figure.

Detailed ways

The serial numbers in the figure respectively indicate: connecting bolt 1, elastic pad 2, washer 3, positioning seat 4, rear end cover 5, fixing through hole 5a, input end 6, driving power supply 7, output end 8, annular cylinder 9, heat dissipation Sheet 10, cooling channel 10a outside the bowl, cooling channel 10b inside the bowl, washer 11, fixing bolt 12, bracket 12a, LED bulb 13, positive electrode 13a, negative electrode 13b, backing plate 14, lens 15, reflective bowl 15a, lens pressing cover 16. Connecting bolt seat 16a, sealing ring 17, fixing hole 18, housing 19, sealing ring 20, rubber ring 21, sealing bolt 22.

See Figure 1. The front of the lamp is from the center to the outside, followed by lens 15, lens compression cover 16, heat sink 10, reflective bowl 15a, housing 19, and lens 15 is pressed and fixed by lens compression cover 16. The cooling fins 10 are radially arranged, and the front end of the cooling fins 10 forms a conical concave ring surface with the lens 15 as the center, and the reflective bowl 15a is arranged on the ring surface. The inner and outer regions of the reflective bowl 15a are distributed with cooling fins 10, and the cooling channels 10a outside the bowl and the cooling channels 10b inside the bowl surrounded by the adjacent cooling fins 10. Although this structure is simple, it is particularly beneficial to heat dissipation because the air can flow forward and backward. (This is the most important innovation point of the utility model), based on this innovation point, the width of the reflective bowl 15a, the conical concave annular surface taper that all heat sink front faces form, and the heat dissipation channel 10a outside the bowl, inside the bowl The setting width of the cooling channel 10b or whether it should be set can be considered and adjusted in combination with the curvature of the lens 15, so as to achieve the best reflective effect.

Whether the bracket 12a is set on the shell 19 can be determined according to the purpose of the lamp. For example, the bracket 12a is set for a tunnel lamp. It can be rotated 360 degrees, so the irradiation angle of the lamp body can be adjusted.

Fig. 2 is a schematic bottom view of Fig. 1 . Since the power supply assembly and the lamp body in this embodiment are an integral structure, the annular cylinder in the middle of the housing is relatively thick, so the rear end surface of the heat sink 10 can be properly extended to cover the entire outer wall of the annular cylinder. To dissipate the heat generated by the drive power circuit. It can be seen from Fig. 2 that the connecting bolt 1 fixes the rear end cover 5 through the fixing through hole 5a. There is a through hole in the middle part of the sealing bolt 22, which is mainly used to lead out the input wire of the driving power supply in a sealed state. Its detailed structure is further illustrated by Fig. 3 .

FIG. 3 is a schematic diagram of the exploded structure of the components in FIG. 1 , and the bracket structure is not shown in the figure.

The shell 19 is annular (certainly also depending on the situation, the shell 19 can be designed into square, pentagonal and other polygonal shapes), and the two sides on the wall are provided with screw holes for receiving the fixing bolts 12. The screw holes have internal threads, and the bracket 12a is formed by It is tightly matched and positioned, and after positioning, the bracket 12a can rotate 360 degrees around the fixing bolt 12, so as to adjust the irradiation angle of the lamp body. Heat dissipation through holes can also be arranged on the wall as required, so as to increase air circulation channels from left to right. Radial cooling fins 10 are arranged inside the casing 19, and the cooling fins 10 are arranged axially, and their outer ends are connected to the inner wall of the casing 19, and their inner ends are connected to the annular cylinder 9 in a fence shape. form an air passage.

During specific implementation, the above-mentioned annular cylinder body 9 has two configuration forms, one is to install the driving power supply 7 directly in the annular cylinder body 9; the other way is to separate the driving power supply 7 and the annular cylinder body 9 separately After setting, lead the power output line to the annular cylinder 9 and electrically connect with the LED bulb 13. In this way, the diameter of the annular cylinder 9 can be smaller, and its axial length can also be shorter. This embodiment adopts the former method, that is, the driving power supply 7 is directly installed in the annular cylinder 9 .

In FIG. 3 , the annular cylinder 9 is used to receive the driving power supply 7 , and the output terminals 8 of the driving power supply 7 are respectively electrically connected to the positive pole 13 a and the negative pole 13 b of the LED light bulb 13 . The LED bulb 13 is fixedly positioned at the front end of the annular cylinder 9, the middle part of the circular backing plate 14 has a through hole, and the through hole is used to receive the LED bulb, and the bottom ring edge of the lens 15 can be embedded in the circumference of the front end of the annular cylinder 9 Inside. The lens pressing cover 16 is ring-shaped, and the lens 15 can protrude from the middle thereof, and its connecting bolt seat 16a is used to receive the connecting bolt 1, and the sealing ring 17 is arranged on the plane where the lens pressing cover 16 contacts the bottom ring edge of the lens 15 .

After the driving power supply 7 is fixed in the annular cylinder 9, the wires of the power supply input end 6 are drawn out in a sealed manner from the positioning seat 4, the sealing rubber ring 21 and the through hole in the middle of the sealing bolt 22 on the rear end cover 5 to connect to the power supply. There are six fixing through holes 5a on the rear end cover 5, respectively receiving 6 connecting bolts 1, and the 6 connecting bolts 1 respectively pass through the six fixing through holes 5a and are screwed on the connecting bolt seats 16a, so as to seal and fix the relevant parts on the Inside the annular cylinder 9 , the lens 15 is fixed on the front end of the annular cylinder 9 .

The key innovation point of the utility model is the setting form of the heat sink 10, so as to achieve the effect of ventilation in the front, back, left, and right. Therefore, high-power LED lights such as tunnel lights, flood lights, and street lights similar to the structure of this example can use the above-mentioned Structure is designed. Of course, those skilled in the art may design various forms of deformed structures by referring to the innovation points of this patent, for example, the front and rear air ducts are arc-shaped structures, etc. However, such deformed high-power LED lamps should also be included in the protection of this patent scope.

Claims (9)

1. A high-power LED explosion-proof lamp, comprising: a housing (19), a light-emitting component, and a heat sink (10); the light-emitting component includes a reflective bowl (15a), an LED bulb (13) and a lens (15), and is characterized in that: The cooling fins (10) are radially arranged in the channel of the casing, the outer end of each cooling fin (10) is connected to the inner wall of the casing (10), and the inner end is connected with the outer wall of an annular cylinder (9). The front end face of the sheet (10) forms a tapered concave annulus, and the reflective bowl (15a) is arranged on the annulus; the axis of the annular cylinder (9) coincides with the axis of the housing, and the annular cylinder (9) The front end face of the LED bulb (13) and the lens (15) are installed on the plane. 2. The high-power LED explosion-proof lamp according to claim 1, characterized in that: the drive power supply (7) is installed in the ring-shaped cylinder (9), and the front end of the ring-shaped cylinder (9) has a lens pressing Cover (16), the rear portion is provided with rear end cover (5), and lens (15) is installed between annular barrel (9) front end surface and lens compression cover (16). 3. The high-power LED explosion-proof lamp according to claim 1 or 2, characterized in that: the shell (19), heat sink (10), annular cylinder (9) and reflective bowl (15a) are integral parts . 4. The high-power LED explosion-proof lamp according to claim 1, characterized in that: the areas other than the inner and outer rings of the reflective bowl (15a) are distributed with heat dissipation channels formed by fence-shaped heat sinks. 5. The high-power LED explosion-proof lamp according to claim 2, characterized in that: the lens pressing cover (16), the annular cylinder (9) and the rear end cover (5) are connected by connecting bolts (1) Into a sealed whole. 6. The high-power LED explosion-proof lamp according to claim 1, characterized in that: the shell (19) is cylindrical in shape. 7. The high-power LED explosion-proof lamp according to claim 1, characterized in that: the shell (19) is polygonal in shape. 8. The high-power LED explosion-proof lamp as claimed in claim 1, characterized in that: the housing (19) is provided with a positioning bracket. 9. The high-power LED explosion-proof lamp as claimed in claim 1, characterized in that: the shell (19) is provided with heat dissipation through holes.

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