TWM521153U - LED explosion-proof lamp mask - Google Patents

Description

LED explosion-proof lampshade

The present invention relates to an LED explosion-proof lampshade, especially an LED explosion-proof lampshade whose surface is smooth and easy to clean and is suitable for use in a dangerous environment such as flammable or high dust.

Light-E1mitting DiodE1 (LED) has the advantages of small size, high brightness and long service life. However, in high temperature environment, the life of the LED can be significantly shortened. In the case of explosion-proof lamps, in order to avoid the flammable gas outside the high-temperature ignition lamp generated by the explosion of electrical appliances in the lamp, the space inside the lamp must be sealed. This requirement makes the waste heat more difficult to escape.

After continuous research and improvement, explosion-proof lighting fixtures using light-emitting diodes as light sources have been developed, and the waste heat generated by the operation of the light-emitting diodes is transmitted through conduction, and the heat-conducting materials are connected to reduce the thermal resistance, so that the waste heat is smooth. The heat-dissipating fins that are transmitted to the outside of the luminaire achieve lower energy consumption at the same or even higher illumination requirements.

However, the heat dissipation effect of the heat dissipation fins is related to its surface area, so it is usually arranged in a domino shape or a fin shape. Although such a setting can increase the heat dissipation efficiency, the grooves and depressions of the fin itself are likely to cause dust and dirt accumulation. It is necessary to clean and maintain regularly to maintain the original heat dissipation effect. If the explosion-proof lamps are set in a high dust working environment, the high temperature explosion-proof lampshade will be in contact with the dust, which will increase the risk of dust storms. Therefore, how to improve the lack of heat dissipation fins in the prior art and ensure the heat dissipation effect of the explosion-proof lamps is indeed an issue that the industry is eager to overcome.

The purpose of the present invention is to solve the problems in the above-mentioned prior art that the explosion-proof lamps used in the prior art use heat-dissipating fins to cause dust to accumulate easily, which causes inconvenience in cleaning and increases the risk of dust storms.

In order to achieve the above object, the present invention provides an LED explosion-proof lampshade for isolating a lighting module and an external environment, the LED explosion-proof lampshade comprising a body and a cover. The body includes a casing having a substantially spherical shape, a receiving groove connected to the recessed portion of the casing, and a wiring hole extending through the body and the receiving groove, the receiving groove includes a surrounding of the wiring hole and a first platform disposed for the lighting module, a second platform disposed around the first platform and having a step difference from the first platform, and a ring wall disposed around the second platform. The cover body includes a light-transmitting plate that is disposed on the second platform and covers the lighting module, and is pressed against the light-transmitting plate on the second platform and is tightly connected to the annular pressing member of the ring wall, wherein the cover plate a shell edge away from the one end of the wiring hole defines a shell edge, the plane surrounding the shell edge defines a circular bottom surface A1, the maximum distance from the circular bottom surface A1 to the outer shell defines a height h, the circular bottom surface A1 and the The height h meets the following relationship: (Formula 1)

Further, the power of the lighting module is W, and the surface between the wiring hole and the edge of the shell defines a smooth curved surface A2, and the surface between the shell edge and the receiving groove defines an inner heat dissipating surface A3, and the smooth curved surface A2 The sum of the areas of the inner heat dissipating surface A3 is proportional to the power W.

Further, the body includes a plurality of heat dissipating fins disposed on the smooth curved surface A2 and radially arranged around the wiring hole.

Further, each of the heat dissipation fins has a heat dissipation tip disposed facing the wiring hole, and a height of each of the heat dissipation fins is gradually decreased toward the heat dissipation tip, and a maximum height thereof is less than 10 mm.

Further, the outer casing includes a plurality of heat dissipation grooves recessed in the smooth curved surface A2 and arranged in a radiation centering on the wiring holes.

Further, the outer casing includes a plurality of heat dissipation grooves recessed on the smooth curved surface A2.

Further, the ring wall is provided with an internal thread, and the cover body comprises a ring disposed around the annular pressing member and threaded outside the internal thread.

Further, the body includes a plurality of heat dissipation ribs disposed between the outer casing and the accommodating groove.

Further, the lighting module includes a heat dissipating substrate and a light source connected to a side of the heat dissipating substrate, the receiving slot includes a first portion and the second platform and the first The platform has a third platform with a step, and each of the portions of the light source not connected to the heat dissipation substrate is in contact with the third platform.

Further, the cover body comprises two pressing rings respectively disposed between the light-transmitting plate and the second platform and the annular pressing member.

Therefore, this creation has the following beneficial effects compared to the prior art:

1. By controlling the geometric proportion of the lampshade, the creation of the LED explosion-proof lampshade surface presents a smooth curved surface, and at the same time ensures the heat dissipation effect, which can improve the problem that the design of the heat-dissipating fins is difficult to remove the dust and dirt, and at the same time reduce the manufacturing mold. cost.

2. The creation is connected to the lighting module through the first and third platforms, so that the heat energy is more easily transmitted and the outer casing is dissipated, and the light-transmitting plate and the second platform are pressed by the annular pressing member to further strengthen the curing LED explosion-proof lampshade. structure. In addition, the annular pressing member is locked with the ring wall through the thread, which can isolate the inner and outer space of the lamp, conforms to the international electrical specifications for use in a dangerous environment, and has the advantages of simplifying the component.

For a more detailed description of the technical features and operation modes of the present application, and with reference to the illustrations, please refer to the review. In addition, the drawings in this creation are not necessarily drawn to scale in order to facilitate the description, and the proportions in the drawings are not intended to limit the scope of the claimed invention.

Regarding the technology of the present creation, please refer to FIG. 1 , the present invention provides an LED explosion-proof lampshade 100 for isolating a lighting module 30 from an external environment. The foregoing external environment is particularly directed to a hazardous environment such as a flammable or explosive substance, such as a petrochemical plant, a coal fired plant, or a plant having a high dust content. However, the above is merely an example, and the environment to which it is applied is not limited herein.

Specifically, the LED explosion-proof lamp cover 100 includes a body 10 and a cover 20 . The body 10 includes a housing 11 having a substantially spherical shape, a receiving slot 12 connected to the recessed portion of the housing 11, and a wiring hole 13 extending through the body 10 and the receiving slot 12. The body 10 is made of a metal material having a better heat transfer efficiency and corrosion resistance, such as an aluminum alloy. The outer casing 11 is substantially in the shape of a shallow dish, and the receiving groove 12 is disposed in the recess of the outer casing 11. At the inner edge of the center. The accommodating slot 12 is configured to receive the lighting module 30 and other components, and includes a first platform 121 surrounding the wiring hole 13 and disposed by the lighting module 30, and is disposed around the first platform 121 and A second platform 122 having a step difference from the first platform 121 and a ring wall 123 disposed around the second platform 122.

The cover body 20 includes a light-transmitting plate 21 that is disposed on the second platform 122 and covers the lighting module 30. The light-transmitting plate 21 is pressed against the light-transmitting plate 21 on the second platform 122 and is tightly connected to the ring wall 123. Annular compression member 22. The light-transmitting plate 21 may be a light-transmitting material such as glass or acryl, and the annular pressing member 22 is made of an aluminum alloy or the same material as the outer casing 11. In this embodiment, the ring wall 123 is provided with an internal thread 1231. The cover body 20 includes a ring disposed around the annular pressing member 22 and corresponding to the external thread 1211. The cover body 20 includes two The pressing ring 23 is disposed between the light-transmitting plate 21 and the second platform 122 and the annular pressing member 22 respectively. Therefore, the user only needs to simply screw the annular pressing member 22 into the ring wall 123 to engage the light-transmitting plate 21, and each of the pressing rings 23 is deformed to seal the receiving groove 12. The space inside. However, the connection manner between the ring wall 123 and the annular pressing member 22 is only for the explanation of the example. In the implementation, a combination of a screw (not shown) and a screw hole (not shown) may be used. Limited.

Referring to FIG. 1 and FIG. 2, a shell edge E1 is defined on one end of the outer casing 11 away from the wiring hole 13. The plane surrounded by the shell edge E1 defines a circular bottom surface A1. The maximum distance to the outer casing 11 defines a height h, and the circular bottom surface A1 and the height h conform to the following relationship: (Formula 1)

In the above relation, the constant k is the height h is a multiple of the diameter of the circular bottom surface A1. In the present creation, the setting k is between 2 and 6. In other words, the outer casing 11 can be regarded as a complete spherical shell along a The portion of the plane (i.e., the circular bottom surface A1) is cut, and the diameter of the circular bottom surface A1 is 2 to 6 times the height h of the outer circumference of the outer casing 11 to the circular bottom surface A1. Since the foregoing relationship restricts the shape of the outer casing 11 to a shallow dish, the propagation path of the waste heat is short, and waste heat can be uniformly transmitted to the surface of the outer casing 11. Further, the power of the illumination module 30 is W, and the curved surface of the surface of the surface of the surface of the surface of the surface of the surface of the surface of the surface of the surface of the surface of the surface of the surface of the surface of the surface of the surface The surface between the surfaces defines an inner heat dissipating surface A3, and the sum of the area of the smooth curved surface A2 and the inner heat dissipating surface A3 is proportional to the power W. Derived from the experimental experience, according to the architecture of the creation, if the average temperature of the workplace is 40 ° C, to maintain the surface temperature of the LED explosion-proof lamp cover 100 to be below 70 ° C, the power module 30 increases the power W by 1 watt. Then, the sum of the area of the smooth curved surface A2 and the inner heat radiating surface A3 must be increased to 18 cm 2 to 25 cm 2 . For example, if the power W is 75 watts, then: 1875 cm 2 ≥ A2 + A3 ≥ 1350 cm 2

According to this, the light-emitting diode can be prevented from being excessively dissipated without additional fins, and the surface of the LED explosion-proof lampshade 100 has a smooth curved surface, which not only saves cost in mold manufacturing, but also achieves difficulty in accumulating dirt and Dust ensures safety.

Referring to FIG. 1 , FIG. 3-1 , and FIG. 3-2 , in the embodiment, the illumination module 30 includes a heat dissipation substrate 31 and a portion connected to the heat dissipation substrate 31 . Light source 32. Each of the light sources 32 is partially connected to one side of the heat dissipation substrate 31, and has a vertical height difference of the bottom surface of each of the light sources 32 and the heat dissipation substrate 31 as shown in FIG. 3-2. The slot 12 includes a third platform 124 between the first platform 121 and the second platform 122 and having a step difference with the first platform 121. Each of the light sources 32 is not connected to the heat sink substrate 31. Contacting the third platform 124, the thermal energy on the heat dissipation substrate 31 can be conducted to the first platform 121, and part of the thermal energy of the light source 32 can also be transmitted to the third platform 124 to escape. Achieve better heat dissipation.

In addition, the light source 32 is generally disposed toward the ground, so that the inner heat dissipating surface A3 generally does not accumulate dust and dirt. To further improve the heat dissipation efficiency, the body 10 includes a plurality of the outer casing 11 and the receiving groove 12 . The heat dissipating ribs 14 therebetween, thereby increasing the surface area of the inner heat dissipating surface A3. In order to improve the heat dissipation effect of the LED explosion-proof lampshade 100, as shown in FIGS. 4-1 and 4-2, the body 10 includes a plurality of the smooth curved surface A2 and is radiated around the wiring hole 13 Arranging the heat dissipation fins 111, the height h of each of the heat dissipation fins 111 is less than 10 mm, because the difference between each of the heat dissipation fins 111 and the smooth curved surface A2 is not large, and the cleaning dust is not difficult, and the dust can be accumulated. The amount is negligible = negligible. Each of the heat dissipation fins 111 has a heat dissipation tip 1111 disposed facing the wiring hole 13 , and the height h of each of the heat dissipation fins 111 is gradually decreased toward the heat dissipation tip 1111 , so that the top surface of the dust is most easily accumulated. , still maintain a smooth surface, can more effectively reduce the amount of dust accumulation.

Referring to FIGS. 5-1 and 5-2, in another embodiment, the housing 11 includes a plurality of heat dissipation recessed in the smooth curved surface A2 and radiated in the center of the wiring hole 13 . Slot 112. Since each of the heat dissipation slots 112 can generate irregularities on the smooth curved surface A2, thereby increasing the surface area thereof and increasing the heat dissipation efficiency thereof, and each of the heat dissipation slots 112 is only some micro protrusions disposed on the smooth curved surface A2 or Shallow trenches are less prone to dust accumulation. Moreover, the outer casing 11 includes a plurality of heat-dissipating grooves (not shown) which are recessed on the smooth curved surface A2 to further improve the heat dissipation efficiency.

In summary, by defining the geometric proportion of the LED explosion-proof lampshade, the creation of the LED explosion-proof lampshade top surface is set to a smooth plane, or slightly undulating concave and convex surface, so that the dirt dust is not easy to accumulate, and it is easy to clean and avoid dust storm accident. efficacy. In addition, the creation has an excellent effect of facilitating assembly through the arrangement of the annular pressing member and the ring wall. Moreover, the creation of the heat dissipating fins in the same direction as the light source can prevent dust accumulation even while maintaining heat dissipation efficiency.

100‧‧‧LED explosion-proof lampshade
10‧‧‧ Ontology
11‧‧‧Shell
111‧‧‧Heat fins
1111‧‧‧heat tip
112‧‧‧heat sink
12‧‧‧ accommodating slots
121‧‧‧First platform
122‧‧‧Second platform
123‧‧‧Circle wall
1231‧‧‧ internal thread
124‧‧‧ Third platform
13‧‧‧ wiring holes
14‧‧‧ Heat dissipation ribs
20‧‧‧ cover
21‧‧‧Translucent plate
22‧‧‧Circular compression parts
221‧‧‧ external thread
23‧‧‧ pressing ring
30‧‧‧Lighting module
31‧‧‧ Thermal substrate
32‧‧‧Light source
A1‧‧‧round bottom
A2‧‧‧Smooth surface
A3‧‧‧ inside heat sink
H‧‧‧height
E1‧‧‧ shell edge

Fig. 1 is an exploded perspective view showing the first embodiment of the present invention. Figure 2: Side view of the first embodiment of the creation. Figure 3-1: A three-dimensional combination of the first embodiment of the creation. Figure 3-2: is a cross-sectional view of the 3-1 position at the A-A position. Figure 4-1: A three-dimensional combination of the second embodiment of the present invention. Figure 4-2: is a cross-sectional view of the Figure 4-1 at the B-B position. Figure 5-1: A three-dimensional combination of the third embodiment of the creation. Figure 5-2: is a cross-sectional view of the 5-1th position at the C-C position.

100‧‧‧LED explosion-proof lampshade

10‧‧‧ Ontology

11‧‧‧Shell

12‧‧‧ accommodating slots

121‧‧‧First platform

122‧‧‧Second platform

123‧‧‧Circle wall

1231‧‧‧ internal thread

124‧‧‧ Third platform

13‧‧‧ wiring holes

14‧‧‧ Heat dissipation ribs

20‧‧‧ cover

21‧‧‧Translucent plate

22‧‧‧Circular compression parts

221‧‧‧ external thread

23‧‧‧ pressing ring

30‧‧‧Lighting module

31‧‧‧ Thermal substrate

32‧‧‧Light source

A3‧‧‧ inside heat sink

E1‧‧‧ shell edge

Claims (10)

An LED explosion-proof lampshade is used for isolating a lighting module and an external environment. The LED explosion-proof lampshade comprises: a body comprising a casing having a substantially spherical shape, and a receiving groove connected to the concave portion of the casing And a wiring hole extending through the body and the receiving slot, the receiving slot includes a first platform surrounding the wiring hole and disposed by the lighting module, and a first surrounding the first platform and the first The platform has a second platform with a step difference, and a ring wall disposed around the second platform; and a cover body including a light-transmitting plate that is disposed on the second platform and covers the lighting module, and is pressed against the The light transmissive plate is connected to the annular pressing member of the annular wall, and the outer edge of the outer casing defines a shell edge, and a plane surrounding the shell edge defines a circular bottom surface A1. The maximum distance from the circular bottom surface A1 to the outer casing defines a height h, and the circular bottom surface A1 and the height h conform to the following relationship: . The LED explosion-proof lampshade of claim 1, wherein the power of the lighting module is W, the surface between the wiring hole and the shell edge defines a smooth curved surface A2, and the surface between the shell edge and the receiving groove An inner heat dissipating surface A3 is defined, and the sum of the area of the smooth curved surface A2 and the inner heat dissipating surface A3 is proportional to the power W. The LED explosion-proof lampshade of claim 2, wherein the body comprises a plurality of heat dissipating fins disposed on the smooth curved surface A2 and arranged in a radiation manner around the wiring hole. The LED explosion-proof lamp cover of claim 3, wherein each of the heat dissipation fins has a heat dissipation tip disposed facing the wiring hole, and a height of each of the heat dissipation fins is gradually decreased toward the heat dissipation tip. The maximum height is less than 10mm. The LED explosion-proof lampshade of claim 2, wherein the outer casing comprises a plurality of heat dissipation grooves recessed in the smooth curved surface A2 and arranged in a radiation arrangement around the wiring hole. The LED explosion-proof lampshade of claim 2, wherein the outer casing comprises a plurality of heat dissipation grooves recessed on the smooth curved surface A2. The LED explosion-proof lampshade of claim 1, wherein the ring wall is provided with an internal thread, and the cover body comprises a ring disposed around the annular compression member and threaded outside the internal thread. The LED explosion-proof lampshade of claim 1, wherein the body comprises a plurality of heat dissipation ribs disposed between the outer casing and the accommodating groove. The LED explosion-proof lamp cover of claim 1, wherein the illumination module comprises a heat dissipation substrate, and a light source connected to a side of the heat dissipation substrate, the receiving groove includes a first platform And a third platform between the second platform and the first platform, wherein each portion of the light source not connected to the heat dissipation substrate is in contact with the third platform. The LED explosion-proof lampshade of claim 1, wherein the cover body comprises two pressing rings respectively disposed between the light-transmitting plate and the second platform and the annular pressing member.