CN106247184A - A kind of energy-saving LED lamp - Google Patents

Abstract

The invention discloses an energy-saving LED lamp, wherein connecting rods are respectively arranged on two sides of the upper end of a supporting base, an LED lamp device capable of swinging relative to the connecting rods so as to adjust the light emitting angle is arranged between the connecting rods, an adjusting bolt capable of fixing the LED lamp device is arranged on the connecting rods, the LED lamp device comprises a radiator, an installation groove is arranged at the upper end of the radiator, a PCB is arranged in the installation groove, LED lamp beads are arranged on the PCB, a lens is arranged at the upper end of the radiator, a connecting part is arranged at the lower end of a radiating cylinder, a plurality of radiating holes capable of penetrating through the connecting part along the axial line direction of the radiating cylinder are arranged on the connecting part, and an exhaust fan device capable of supplying air to the radiating holes and the inner cavity of. The invention aims to provide an energy-saving LED lamp.

Description

A kind of energy-saving LED lamp

technical field

The invention relates to an energy-saving LED lamp.

Background technique

The irradiation angle of the existing lamps is generally fixed, which cannot meet the needs of users. Existing LED lamps generally use fixed-shaped radiators to dissipate heat. In order to increase the heat dissipation area, heat dissipation fins are generally densely distributed on the outer wall of the radiator. Seriously affected its service life. Existing radiators used for LED lamps are relatively large in size, require large storage space, and increase transportation costs.

Therefore, the existing lamps need to be further improved.

Contents of the invention

The object of the present invention is to provide an energy-saving LED lamp in order to overcome the deficiencies in the prior art.

In order to achieve the above object, the present invention adopts the following scheme:

An energy-saving LED lamp, comprising a support base, connecting rods are respectively arranged on both sides of the upper end of the support base, and an LED lamp device capable of swinging relative to the connecting rods to adjust the light emitting angle is arranged between the connecting rods. The connecting rod is provided with an adjusting bolt that can fix the LED lamp device. The LED lamp device includes a radiator, and a mounting groove is provided at the upper end of the radiator, and a PCB board is provided in the mounting groove. LED lamp beads are arranged on the PCB board, a lens is arranged at the upper end of the radiator, and a lampshade capable of fixing the lens on the radiator is arranged at the upper end of the radiator, and the lens includes a truncated conical lens body , a cylindrical lens body is integrally formed on the upper end surface of the truncated conical lens body, the lower end surface of the cylindrical lens body completely coincides with the upper bottom surface of the truncated conical lens body, and the upper end surface of the truncated conical lens body The diameter of the bottom surface is greater than the diameter of the lower bottom surface, a light inlet groove is provided at the bottom of the truncated conical lens body, and a truncated conical groove is provided at the upper end of the cylindrical lens body. The upper end surfaces of the cylindrical lens body are completely overlapped, and a convex spherical lens body is integrally formed upward on the cylindrical lens body at the lower bottom surface of the truncated conical groove, and the bottom surface of the convex spherical lens body is It completely coincides with the bottom surface of the conical truncated groove, the LED lamp bead is arranged in the light inlet groove, a connecting part is provided at the lower end of the heat dissipation cylinder, and a plurality of heat dissipation cylinders are arranged on the connection part. The axial direction passes through the cooling hole of the connecting portion, and the connecting portion is connected with an exhaust fan device capable of blowing air to the cooling hole and the internal cavity of the radiator.

An energy-saving LED lamp as described above is characterized in that the exhaust fan device includes a ventilating mounting seat, and the venting mounting seat is connected to the lower end of the heat dissipation cylinder through a connecting screw. fan.

An energy-saving LED lamp as described above is characterized in that the radiator includes a heat dissipation cylinder, a number of heat dissipation fins are arranged on the outer wall of the heat dissipation cylinder, The main body of the radiator that the cylinder rotates is provided with a cavity in the main body of the radiator, the inner wall of the main body of the radiator is evenly distributed with cooling fins, and the outer wall of the main body of the radiator is provided with a plurality of retractable The heat dissipation fins on the radiator main body are provided with a plurality of guide grooves on the heat dissipation cylinder, and the heat dissipation fins are arranged in the guide grooves.

The above-mentioned energy-saving LED lamp is characterized in that a connection concave platform is provided on the inner wall of the upper end of the heat dissipation cylinder, and a connecting convex platform is provided on the upper end of the radiator main body, and the connecting convex platform is movably arranged on the connecting concave platform. In the platform, the installation groove is arranged on the connecting boss.

The above-mentioned energy-saving LED lamp is characterized in that a knob portion capable of driving the radiator main body to rotate is provided at the end of the radiator main body.

The above-mentioned energy-saving LED lamp is characterized in that heat dissipation holes communicating with the inside and outside of the heat dissipation cylinder are provided on the outer wall of the heat dissipation cylinder.

An energy-saving LED lamp as described above is characterized in that the guide groove runs through the upper end of the heat dissipation cylinder.

The above-mentioned energy-saving LED lamp is characterized in that the heat dissipation sheet is integrally formed with the heat sink main body.

The present invention is provided with a suction cup on the bottom surface of the support base.

In summary, the present invention has the beneficial effects relative to the prior art as follows:

The invention has a simple structure, and the radiating fins on the main body of the radiator can be stretched to effectively increase the radiating area and transfer heat away from the expandable radiator, thereby greatly improving the radiating effect. In the present invention, the radiating sheet can be crimped on the outer wall of the main body of the radiator, thereby reducing the volume and facilitating storage and transportation.

The lens of the invention has unique design and good light effect.

Description of drawings

Fig. 1 is the sectional schematic diagram of lamps and lanterns of the present invention;

Fig. 2 is the schematic diagram of supporting base and connecting rod of the present invention

Fig. 3 is the three-dimensional schematic view of radiator of the present invention;

Fig. 4 is a schematic cross-sectional view of the radiator of the present invention.

detailed description

The present invention will be further described below in conjunction with specific embodiment:

As shown in Figures 1-4, an energy-saving LED lamp according to the present invention includes a support base 300, connecting rods 3001 are respectively provided on both sides of the upper end of the support base 300, and connecting rods 3001 are provided with opposing The connecting rod 3001 swings to adjust the light emitting angle of the LED lamp device 800. The connecting rod 3001 is provided with an adjusting bolt 3002 that can fix the LED lamp device 800. An adjusting hole is provided on the LED lamp device 800. The adjusting bolt 3002 is set in the adjustment hole. When the LED lamp device 800 is adjusted to the required light emitting angle, the LED lamp device 800 can be fixed on the connecting rod 3001 according to the required angle by twisting the adjusting bolt 3002. The LED lamp device 800 Including a heat sink 100, a mounting groove 101 is provided at the upper end of the heat sink 100, a PCB board 102 is provided in the mounting groove 101, an LED lamp bead 103 is provided on the PCB board 102, and the heat dissipation The upper end of the device 100 is provided with a lens, and the upper end of the radiator 100 is provided with a lampshade 900 capable of fixing the lens on the radiator 100. The lens includes a truncated conical lens body 10. The upper end surface of 10 is integrally formed with a cylindrical lens body 20, the lower end surface of the cylindrical lens body 20 completely overlaps with the upper bottom surface of the truncated conical lens body 10, and the diameter of the upper bottom surface of the truncated conical lens body 10 is larger than The diameter of the lower bottom surface is provided with a light inlet groove 30 at the bottom of the truncated conical lens body 10, and a truncated conical groove 40 is provided at the upper end of the cylindrical lens body 20, and the upper bottom surface of the truncated cone shape groove 40 It completely coincides with the upper end surface of the cylindrical lens body 20, and an outwardly convex spherical segment-shaped lens body 50 is integrally formed upward on the cylindrical lens body 20 at the lower bottom surface of the truncated conical notch 40, and the outwardly convex spherical segment The bottom surface of the shaped lens body 50 completely coincides with the bottom surface of the truncated conical notch 40 , and the LED lamp bead 103 is arranged in the light entrance groove 30 .

The radiator 100 of the present invention includes a heat dissipation cylinder 1, a plurality of heat dissipation fins 11 are provided on the outer wall of the heat dissipation cylinder 1, and a fin that can rotate relative to the heat dissipation cylinder 1 is provided in the heat dissipation cylinder 1. The radiator main body 2 is provided with a cavity 21 in the radiator main body 2, and radiating fins 11 are evenly distributed on the inner wall of the radiator main body 2, and a plurality of energy The heat dissipation sheet 3 crimped on the radiator main body 2 is provided with a plurality of guide grooves 4 on the heat dissipation cylinder 1 , and the heat dissipation sheet 3 is arranged in the guide groove 4 . A connecting portion 9 is provided at the lower end of the heat dissipation cylinder 1, and a plurality of heat sinks 8 that can pass through the connection portion 9 along the axial direction of the heat dissipation cylinder 1 are provided on the connection portion 9. An exhaust fan device 400 capable of blowing air to the cooling holes 8 and the cavity 21 .

The exhaust fan device 400 of the present invention includes a ventilation installation seat 4001, which is connected to the lower end of the heat dissipation cylinder 1 through connecting screws, and a fan 4002 is arranged in the ventilation installation seat.

The light inlet groove 30 of the present invention includes a cylindrical slot, and the side wall of the cylindrical slot is provided with a convex arc-shaped convolution lens body 301, and the convex arc-shaped convolution lens body 301 and the truncated conical lens The body 10 is integrally formed, and the convex lens body 302 is provided on the truncated conical lens body 10 at the upper end surface of the cylindrical notch.

In the present invention, a connection concave platform 5 is provided on the inner wall of the upper end of the heat dissipation cylinder 1, and a connecting convex platform 6 is provided on the upper end of the radiator main body 2, and the connecting convex platform 6 is movably arranged in the connecting concave platform 5, so that The mounting groove 101 is provided on the connecting boss 6 . Part of the heat from the radiator main body 2 is transferred to the heat dissipation cylinder 1 through the connecting boss 6, thereby enhancing the heat dissipation effect.

In the present invention, the lampshade 103 includes a cover body 1031 , and a snap ring 1032 is provided at the lower end of the cover body 1031 , and the snap ring 1032 is snapped on the bottom surface of the outer edge of the connecting boss 6 .

In the present invention, a knob portion 7 capable of driving the radiator main body 2 to rotate is provided at the end of the radiator main body 2 . In the present invention, the expansion and contraction of the heat dissipation sheet 3 can be controlled by rotating the knob part 7 .

In the present invention, heat dissipation holes 8 communicating with the inside and outside of the heat dissipation cylinder 1 are provided on the outer wall of the heat dissipation cylinder 1 . The heat dissipation holes 8 are beneficial to the heat exchange between the inside and outside of the heat dissipation cylinder 1 and improve the heat dissipation effect.

The guide groove 4 described in the present invention runs through the upper end of the heat dissipation cylinder 1 . When the heat dissipation cylinder 1 and the heat dissipation sheet 3 are installed, it is only necessary to place the heat dissipation sheet 3 in the guide groove 4 in sequence, and then rotate the radiator main body 2 so that the heat dissipation sheet 3 is curled and stored on the radiator main body 2. In the present invention, the Limiting blocks may be provided at the ends of the heat dissipation sheet 3 to prevent excessive crimping of the heat dissipation sheet 3 .

In the present invention, a connection portion 9 is provided at the lower end of the heat dissipation cylinder 1 , and in the present invention, a heat dissipation hole 8 is provided on the connection portion 9 . Good cooling effect.

In the present invention, the heat dissipation sheet 3 is integrally formed with the radiator main body 2 .

In the present invention, a bearing is sheathed on the outer wall of the connecting boss 6 .

The present invention is provided with a suction cup 1600 on the bottom surface of the support base.

In one of the implementation methods of the present invention, the radiator main body 2 and the heat dissipation sheet 3 are both made of foamed aluminum alloy material, and the foamed aluminum alloy material is composed of the following components by weight percentage:

Aluminum oxide 10-45%

Zinc Oxide 15-30%

Magnesium powder 5-35%

Graphite 8-30%.

Example 1

The foamed aluminum alloy material of the present invention consists of the following components by weight percentage:

Aluminum oxide 10%

Zinc Oxide 30%

Magnesium powder 35%

Graphite 25%.

Example 2

The foamed aluminum alloy material of the present invention consists of the following components by weight percentage:

Aluminum oxide 10%

Zinc Oxide 25%

Magnesium powder 35%

Graphite 30%.

Example 3

The foamed aluminum alloy material of the present invention consists of the following components by weight percentage:

Aluminum oxide 45%

Zinc Oxide 15%

Magnesium powder 10%

Graphite 30%.

Example 4

The foamed aluminum alloy material of the present invention consists of the following components by weight percentage:

Aluminum oxide 45%

Zinc Oxide 25%

Magnesium powder 5%

Graphite 25%.

The radiator main body 2 and the heat dissipation fins 3 described in the present invention can also be made of aluminum alloy or copper.

In the present invention, a heat dissipation coating is sprayed on the outer wall of the radiator to effectively enhance the heat dissipation effect of the radiator. The heat dissipation coating of the present invention comprises the following components by weight:

Further describe heat-dissipating coating of the present invention below by embodiment:

Example 1

The heat dissipation coating of the present invention comprises the following components by weight:

The silicone resin with modified nanoparticles is prepared by the following method:

A. Take 40 parts by weight of methyltriethoxysilane, add 600 parts of water, add 0.06 parts by weight of formic acid catalyst, hydrolyze at 0°C for 1 hour, heat up to 70°C for polymerization reaction, and carry out vacuum distillation after the reaction , to obtain silicone resin;

B. Mix the silicone resin in step A, 8 parts by weight of 1-trifluoromethyl-1,3 butadiene, 0.1 parts by weight of titanate catalyst and 10 parts by weight of ethyl acetate, and mix them uniformly under the protection of argon. , heated to 100°C for dehydration condensation reaction for 1 hour to obtain modified silicone resin;

C. Raise the temperature of the modified silicone resin in step B to 75°C, add 2 parts of ethyl silicate to react for 1 hour, cool down after the reaction, and distill off the solvent under reduced pressure to obtain the silicone resin containing modified nanoparticles .

Wherein said polyether modified amino silicone oil is prepared according to the following method, comprising the steps of:

S1: Add 300 parts by weight of octamethylcyclotetrasiloxane to a three-necked flask equipped with a stirrer, condenser, and thermometer, stir, heat up to 100°C, add 0.15 parts by weight of catalyst tetramethylammonium hydroxide, and keep warm After 20 minutes, 18 parts by weight of coupling agent N-β(aminoethyl)-γ-aminopropylmethyldimethoxysilane was added, and the temperature was controlled at 100°C for 6 hours to obtain amino silicone oil;

S2: Add 180 parts by weight of the amino silicone oil synthesized in step A, 130 parts by weight of active polyether, and 90 parts by weight of isopropanol into a three-necked flask equipped with a stirrer, a condenser, and a thermometer, and carry out a reflux reaction at 70°C until After the reactant is transparent, continue to keep warm for 4 hours, and finally lower the temperature and reduce the pressure under the condition of 0.005MPa to remove the isopropanol.

The carbon nanotubes of the surface hydroxylation are prepared by the following method:

Mix multi-walled carbon nanotubes and potassium hydroxide in a ball mill tank at a ratio of 1:20 by weight, add an appropriate amount of ethanol, and after ball milling for 12 hours, wash to neutrality with deionized water to obtain a mixture. Put it in a vacuum oven and dry it at 100°C for 12 hours to obtain it.

The solvent is a mixture of xylene and methyl isobutyl ketone in a weight ratio of 2:1.

The preparation method of heat dissipation coating of the present invention:

After mixing epoxy resin, acrylic resin, silicone resin containing modified nanoparticles, and solvent, heat up to 40°C and stir evenly, then add surface hydroxylated carbon nanotubes, polyether modified amino silicone oil, aluminum-magnesium alloy powder, Aluminum nitride, stirred evenly to obtain a mixture, put the mixture into a paint grinder and grind to 30-50 μm, ultrasonically disperse evenly, add polyvinyl acetate and stir evenly.

Example 2

The heat dissipation coating of the present invention comprises the following components by weight:

The silicone resin with modified nanoparticles is prepared by the following method:

A. Take 60 parts by weight of methyltriethoxysilane, add 900 parts of water, add 0.8 parts by weight of formic acid catalyst, hydrolyze at 5°C for 5 hours, heat up to 90°C for polymerization reaction, and carry out vacuum distillation after the reaction , to obtain silicone resin;

B. Mix the silicone resin in step A, 18 parts by weight of 1-trifluoromethyl-1,3 butadiene, 0.6 parts by weight of titanate catalyst and 25 parts by weight of ethyl acetate, and mix them uniformly under the protection of argon. , heated to 120°C for dehydration and condensation reaction for 3 hours to obtain modified silicone resin;

C. Raise the temperature of the modified silicone resin in step B to 95°C, add 14 parts of ethyl silicate to react for 2 hours, cool down after the reaction, and distill off the solvent under reduced pressure to obtain the silicone resin containing modified nanoparticles .

Wherein said polyether modified amino silicone oil is prepared according to the following method, comprising the steps of:

S1: Add 500 parts by weight of octamethylcyclotetrasiloxane to a three-necked flask equipped with a stirrer, condenser, and thermometer, stir, heat up to 125°C, add 0.35 parts by weight of catalyst tetramethylammonium hydroxide, and keep warm After 40 minutes, 22 parts by weight of coupling agent N-β(aminoethyl)-γ-aminopropylmethyldimethoxysilane was added, and the temperature was controlled at 125°C for 6 hours to obtain amino silicone oil;

S2: Add 220 parts by weight of the amino silicone oil synthesized in step A, 180 parts by weight of active polyether, and 120 parts by weight of isopropanol into a three-necked flask equipped with a stirrer, a condenser, and a thermometer, and carry out a reflux reaction at 95°C until After the reactant is transparent, continue to keep warm for 6 hours, and finally lower the temperature and reduce the pressure under the condition of 0.01MPa to remove the isopropanol.

The carbon nanotubes of the surface hydroxylation are prepared by the following method:

Mix multi-walled carbon nanotubes and potassium hydroxide in a ball mill tank at a ratio of 1:30 by weight, add an appropriate amount of ethanol, and after ball milling for 24 hours, wash to neutrality with deionized water to obtain a mixture. Put it in a vacuum oven and dry it at 130°C for 16 hours to obtain it.

The solvent is a mixture of xylene and methyl isobutyl ketone in a weight ratio of 2:1.

The preparation method of heat dissipation coating of the present invention:

After mixing epoxy resin, acrylic resin, silicone resin containing modified nanoparticles, and solvent, heat up to 50°C and stir evenly, then add surface hydroxylated carbon nanotubes, polyether modified amino silicone oil, aluminum-magnesium alloy powder, Aluminum nitride, stirred evenly to obtain a mixture, put the mixture into a paint grinder and grind to 30-50 μm, ultrasonically disperse evenly, add polyvinyl acetate and stir evenly.

Example 3

The heat dissipation coating of the present invention comprises the following components by weight:

The silicone resin with modified nanoparticles is prepared by the following method:

A. Take 50 parts by weight of methyltriethoxysilane, add 750 parts of water, add 0.3 parts by weight of formic acid catalyst, hydrolyze at 2°C for 3 hours, heat up to 80°C for polymerization reaction, and carry out vacuum distillation after the reaction , to obtain silicone resin;

B. Mix the silicone resin in step A, 12 parts by weight of 1-trifluoromethyl-1,3 butadiene, 0.3 parts by weight of titanate catalyst and 15 parts by weight of ethyl acetate, and mix them uniformly under the protection of argon. , heated to 110°C for dehydration and condensation reaction for 2 hours to obtain modified silicone resin;

C. Raise the temperature of the modified silicone resin in step B to 85°C, add 6 parts of ethyl silicate to react for 1.5 hours, cool down after the reaction, and distill off the solvent under reduced pressure to obtain the silicone resin containing modified nanoparticles .

Wherein said polyether modified amino silicone oil is prepared according to the following method, comprising the steps of:

S1: Add 400 parts by weight of octamethylcyclotetrasiloxane to a three-necked flask equipped with a stirrer, condenser, and thermometer, stir, heat up to 110°C, add 0.25 parts by weight of catalyst tetramethylammonium hydroxide, and keep warm After 30 minutes, 20 parts by weight of coupling agent N-β(aminoethyl)-γ-aminopropylmethyldimethoxysilane was added, and the temperature was controlled at 110°C for 6 hours to obtain amino silicone oil;

S2: Add 180-220 parts by weight of the amino silicone oil synthesized in step A, 130-180 parts by weight of active polyether, and 90-120 parts by weight of isopropanol into a three-necked flask equipped with a stirrer, a condenser, and a thermometer. Reflux reaction at 95°C until the reactant is transparent, then continue to keep warm for 4-6 hours, and finally lower the temperature at 0.005-0.01MPa to remove the isopropanol under reduced pressure to obtain the product.

The carbon nanotubes of the surface hydroxylation are prepared by the following method:

Mix multi-walled carbon nanotubes and potassium hydroxide in a ball mill tank at a ratio of 1:25 by weight, add an appropriate amount of ethanol, and after ball milling for 18 hours, wash to neutrality with deionized water to obtain a mixture. Put it in a vacuum oven and dry it at 120°C for 14 hours to obtain it.

The solvent is a mixture of xylene and methyl isobutyl ketone in a weight ratio of 2:1.

The preparation method of heat dissipation coating of the present invention:

After mixing epoxy resin, acrylic resin, silicone resin containing modified nanoparticles, and solvent, heat up to 45°C and stir evenly, add surface hydroxylated carbon nanotubes, polyether modified amino silicone oil, aluminum-magnesium alloy powder, Aluminum nitride, stirred evenly to obtain a mixture, put the mixture into a paint grinder and grind to 30-50 μm, ultrasonically disperse evenly, add polyvinyl acetate and stir evenly.

Example 4

The heat dissipation coating of the present invention comprises the following components by weight:

The preparation method of the organosilicon resin, polyether-modified amino silicone oil, solvent and heat-dissipating coating of the present invention are all the same as those in Example 3.

Example 5

The heat dissipation coating of the present invention comprises the following components by weight:

The preparation method of the organosilicon resin, polyether-modified amino silicone oil, solvent and heat-dissipating coating of the present invention are all the same as those in Example 3.

Example 6

The heat dissipation coating of the present invention comprises the following components by weight:

The preparation method of the organosilicon resin, polyether-modified amino silicone oil, solvent and heat-dissipating coating of the present invention are all the same as those in Example 3.

Example 7

The heat dissipation coating of the present invention comprises the following components by weight:

The preparation method of the organosilicon resin, polyether-modified amino silicone oil, solvent and heat-dissipating coating of the present invention are all the same as those in Example 3.

Example 8

The heat dissipation coating of the present invention comprises the following components by weight:

The preparation method of the organosilicon resin, polyether-modified amino silicone oil, solvent and heat-dissipating coating of the present invention are all the same as those in Example 3.

Example 9

The heat dissipation coating of the present invention comprises the following components by weight:

The preparation method of the organosilicon resin, polyether-modified amino silicone oil, solvent and heat-dissipating coating of the present invention are all the same as those in Example 3.

Example 10

The heat dissipation coating of the present invention comprises the following components by weight:

The preparation method of the organosilicon resin, polyether-modified amino silicone oil, solvent and heat-dissipating coating of the present invention are all the same as those in Example 3.

Example 11

The heat dissipation coating of the present invention comprises the following components by weight:

The preparation method of the organosilicon resin, polyether-modified amino silicone oil, solvent and heat-dissipating coating of the present invention are all the same as those in Example 3.

Example 12

The heat dissipation coating of the present invention comprises the following components by weight:

The preparation method of the organosilicon resin, polyether-modified amino silicone oil, solvent and heat-dissipating coating of the present invention are all the same as those in Example 3.

Example 13

The heat dissipation coating of the present invention comprises the following components by weight:

The preparation method of the organosilicon resin, polyether-modified amino silicone oil, solvent and heat-dissipating coating of the present invention are all the same as those in Example 3.

The basic principles and main features of the present invention and the advantages of the present invention have been shown and described above. Those skilled in the industry should understand that the present invention is not limited by the above-mentioned embodiments. What are described in the above-mentioned embodiments and the description only illustrate the principle of the present invention. Without departing from the spirit and scope of the present invention, the present invention will also have Variations and improvements are possible, which fall within the scope of the claimed invention. The protection scope of the present invention is defined by the appended claims and their equivalents.

Claims (8)

1. an energy-saving LED lamp, includes support base (300), is respectively provided on two sides with in described support base (300) upper end even Extension bar (3001), is provided with between described connecting rod (3001) and relatively connecting rod (3001) can swing thus adjust angular LED lamp device (800), is provided with the regulation bolt that LED lamp device (800) can be made fixing in described connecting rod (3001) (3002), described LED lamp device (800) includes radiator (100), is provided with mounting groove in described radiator (100) upper end (101), in described mounting groove (101), it is provided with pcb board (102), described pcb board (102) is provided with LED lamp bead (103), Described radiator (100) upper end is provided with lens, is provided with lens can be fixed on radiator in described radiator (100) upper end of stating (100) lampshade (900) on, described lens include circular cone shape lenticular body (10), described circular cone shape lenticular body (10) Upper surface on integrally formed with cylinder lenses body (20), the lower surface of described cylinder lenses body (20) is saturating with circular cone shape The upper bottom surface of mirror body (10) is completely superposed, and the diameter of described circular cone shape lenticular body (10) upper bottom surface is more than bottom surface diameter, Described circular cone shape lenticular body (10) bottom is provided with into light groove (30), is provided with the frustum of a cone in described cylinder lenses body (20) upper end Shape short slot (40), the upper bottom surface of described circular cone shape short slot (40) is completely superposed with the upper surface of cylinder lenses body (20), Upwards integrally formed with evagination segment shape lens on cylinder lenses body (20) at described circular cone shape short slot (40) bottom surface Body (50), the bottom surface of described evagination segment shape lenticular body (50) is completely superposed with circular cone shape short slot (40) bottom surface, described LED Lamp bead (103) is arranged in light groove (30), is provided with connecting portion (9) in described radiating cylinder body (1) lower end, at described connecting portion (9) it is provided with multiple louvre (8) that can run through connecting portion (9) along radiating cylinder body (1) axis direction, in described connecting portion (9) Upper connection has the exhaust fan device (400) can blown to louvre (8) and radiating cylinder body (1) internal cavities (21).

A kind of energy-saving LED lamp the most according to claim 1, it is characterised in that described exhaust fan device (400) includes Ventilative mounting seat (4001), described ventilative mounting seat (4001) is connected to radiating cylinder body (1) lower end by attachment screw, described It is provided with fan (4002) in ventilative mounting seat.

A kind of energy-saving LED lamp the most according to claim 1, it is characterised in that described radiator (100) includes heat-dissipating cylinder Body (1), is provided with some radiating fins (11) on described radiating cylinder body (1) outer wall, and being provided with in described radiating cylinder body (1) can phase The radiator body (2) rotated for radiating cylinder body (1), is provided with cavity (21) in described radiator body (2), dissipates described The inner wall even distribution of hot device main body (2) has radiating fin (11), is provided with and multiple can crispatura on described radiator body (2) outer wall Heat radiation thin slice (3) on radiator body (2), is provided with multiple gathering sill (4) on described radiating cylinder body (1), and described heat radiation is thin Sheet (3) is arranged in described gathering sill (4).

A kind of energy-saving LED lamp the most according to claim 3, it is characterised in that inwall sets in described radiating cylinder body (1) upper end Having connection concave station (5), be provided with connection boss (6) in described radiator body (2) upper end, described connection boss (6) is movable to be arranged Within connecting concave station (5), described mounting groove (101) is arranged in connection boss (6).

A kind of energy-saving LED lamp the most according to claim 3, it is characterised in that be provided with in described radiator body (2) end The knob (7) that radiator body (2) rotates can be ordered about.

A kind of energy-saving LED lamp the most according to claim 3, it is characterised in that be provided with on described radiating cylinder body (1) outer wall Louvre (8) inside and outside connection radiating cylinder body (1).

A kind of energy-saving LED lamp the most according to claim 3, it is characterised in that described gathering sill (4) runs through radiating cylinder body (1) upper end.

A kind of energy-saving LED lamp the most according to claim 3, it is characterised in that described heat radiation thin slice (3) and radiator body (2) one-body molded.