KR20110134671A - Energy-saving lighting fixture - Google Patents

Abstract

PURPOSE: An energy saving type lighting apparatus is provided to make a tube type shield with a dual tube structure, thereby saving energy by increasing a heat insulation capacity of the lighting apparatus. CONSTITUTION: A light transmissive tube type shield(70) includes an inner tube(701) and an outer tube(702). A lighting apparatus saves energy by improving a heat insulation capacity. A circuit board(20) is installed in an internal compartment(71) of the tube type shield. The circuit board includes a plurality of semiconductor devices(15), a substrate part(201), and two planar substrate parts(202). A lamp apparatus(30) is fixed in the outer surface of the circuit board. A heat dissipation strip(10) includes a tube type strip main body(101) and a heat dissipation fin(11).

Description

Energy-saving lighting fixtures {ENERGY-SAVING LIGHTING FIXTURE}

The present invention relates to a lighting device, and more particularly, to a lighting device that can save energy.

Recently, in order to protect the environment and reduce power consumption, light emitting diode (LED) lamp tubes are replacing fluorescent tubes. Numerous documents disclose configurations of LED lamp tubes, in each of which a semi-cylinder or square heat dissipation unit is provided to the LEDs of the lamp tube to perform heat dissipation. Attached. However, the heat dissipation unit adversely affects the illuminance of the lamp tube, whereby the light output angle range is limited to about 180 °, which wastes energy. Since the shield of the lamp tube is a single tube structure, the heat generated by the LEDs is conducted directly to the shield, thus increasing the temperature of the lamp tube. As a result, the thermal insulation capability of the LED lamp tubes is poor, and the application range of the lamp tubes is limited.

Therefore, an object of the present invention is to provide a lighting device that can save energy.

According to the present invention, a light-transmissive tubular shield comprising an inner tube having an inner compartment formed therein and an outer tube disposed around the inner tube and spaced apart from the inner tube to form an outer compartment therebetween. Provided is an energy saving lighting fixture comprising. As such, the tubular shield has a double tube structure. The lamp assembly includes at least one lamp device installed to be secured to an inner compartment of the tubular shield.

According to the lighting fixture of the present invention, by implementing a tubular shield having a double tube structure, the effect of improving the heat insulating ability of the lighting fixture and ultimately saving energy can be achieved.

1 is a perspective view of a first preferred embodiment of an energy saving luminaire according to the invention.
2 is an exploded perspective view of the energy saving luminaire of the first preferred embodiment.
3 is a partial cross-sectional view of the energy saving luminaire of the first preferred embodiment.
4 is a schematic cross-sectional view of the energy saving luminaire of the first preferred embodiment.
5 is a partial cross-sectional view of a second preferred embodiment of the energy saving luminaire according to the invention.
FIG. 6 is a plan view of the energy saving luminaire of the third preferred embodiment, illustrating the arrangement of a plurality of lamp devices on a circuit board when laid flat on a plane. FIG.
7 is a partially exploded perspective view of a fourth preferred embodiment of an energy saving lighting fixture according to the present invention.
8 is an exploded perspective view of a fifth preferred embodiment of the energy saving lighting fixture according to the present invention.
9 is a fragmentary partial cross-sectional view of the fifth preferred embodiment.

Other features and advantages of the present invention will become apparent from the following detailed description of the preferred embodiments with reference to the accompanying drawings.

Before describing the present invention in more detail, it should be noted that like elements are designated by like reference numerals throughout the description.

1 and 2 show a first preferred embodiment of an energy saving luminaire 100 according to the invention. The luminaire 100 comprises a heat-dissipating strip 10, a circuit board 20, a lamp assembly with a plurality of lamp devices 30, two control modules 40, 50, two inputs. Terminals 60, and a light transmissive tubular shield 70.

3 and 4, the light transmissive tubular shield 70 forms an outer compartment 72 between an inner tube 701 having an inner compartment 71 formed therein and an inner tube 701. To this end, the tubular shield 70 has a double tube structure because it includes an outer tube 702 installed around the inner tube 701 and spaced apart from the inner tube 701. In this preferred embodiment, the inner compartment 71 has two open ends. The tubular shield 70 is made of a light transmissive material such as glass.

The circuit board 20 is installed in the inner compartment 71 of the tubular shield 70. The lamp devices 30 are installed to be fixed to the inner compartment 71, are connected to be fixed to the outer surface of the circuit board 20, and arranged in three rows. Each row of lamp units 30 is aligned with the adjacent row of lamp units along the circumferential direction of the tubular shield 70. In this preferred embodiment, the lamp devices 30 are light emitting diodes (LEDs). Since the projection angle of each LED is approximately 120 °, the three rows of LEDs provide 360 ° illumination.

The heat dissipation strip 10 includes a tubular strip body 101 having a heat dissipation compartment 12 formed therein, and a plurality of heat dissipation fins extending from the inner surface of the tubular strip body 101 toward the heat dissipation compartment 12. dissipating fins 11.

The tubular strip body 101 of the heat dissipation strip 10 has a base segment 102, two plate segments 103 having a lower end connected to the base segment 102, and two plate segments 103. The upper ends of the heads are connected to each other and have a connecting segment 104 in which a channel 105 is formed. The base segment 102 has an outer surface applied with an insulating colloidal layer 14. The base segment 102 further has two fixing holes 13 formed at both ends thereof and in fluid communication with the heat dissipation compartment 12.

In this preferred embodiment, the circuit board 20 is a flexible printed circuit board and consists of tubes. The heat dissipation strip 10 is provided on the circuit board 20 and is in contact with the circuit board 20. The heat dissipation strip 10 further includes two screws 131 extending through the holes 13 and fitted into the circuit board 20 and the heat dissipation strip 10.

The circuit board 20 includes a plurality of semiconductor elements 15, such as resistors, a base substrate portion 201 aligned with the base segment 102, and two flat substrates aligned with the plate segments 103, respectively. Have portions 202. A portion of each of the semiconductor elements 15 extends through the flat substrate portion 202 and is attached to the insulating colloid layer 14 by a resin slice (not shown). The configuration of the plate segments 103 and the plate substrate portions 202 increases the contact area between the semiconductor elements 15 and the plate segments 103, thereby increasing its heat dissipation capability. Heat generated by the lamp devices 30 and the components of the circuit board 20 (including the semiconductor elements 15) is released to the heat dissipation compartment 12 via the heat dissipation strip 10.

The control modules 40, 50 are provided so as to be connected to both ends of the tubular substrate board 20, respectively. Each of the control modules 40, 50 has base sheets 41, 51 connected to the circuit board 20, and heat dissipation holes 42, 52 in fluid communication with the heat dissipation compartment 12. The control modules 40 and 50 may convert an input current (alternating current) into a direct current, thereby turning the lamp device 30 on / off.

Each of the input terminals 60 has two spaced apart electrode pins 61, 62 and is electrically connected to each one of the control modules 40, 50. The electrode pins 61 and 62 are connected to an electrical socket (not shown) to conduct a direct current to the lamp devices 30.

The tubular shield 70 further includes two spaced connecting walls 703 that connect the inner tube 701 and the outer tube 702 to each other to seal the two ends of the outer compartment 72. It should be noted that outer compartment 72 may not be sealed in other embodiments.

Two cap bodies 73 are provided to seal the two open ends of the tubular shield 70. Two through holes 731 are formed in each of the cap bodies 73. The electrode pins 61, 62 of the input terminals 60 extend through the through holes 731 of the cap bodies 73, respectively. Each of the cap bodies 73 is formed with a corresponding heat dissipation hole 42, 52 of the control modules 40, 50, and ultimately a vent hole 732 in fluid communication with the heat dissipation compartment 12. It is.

It should be noted that the tubular shield 70 is integrally formed in this preferred embodiment. As an alternative, the inner tube 701 and outer tube 702 are formed separately and connected to each other by a glass-welding process.

5, the second preferred embodiment of the energy-saving lighting device 100 according to the present invention has a structure similar to the first embodiment. The main differences between this embodiment and the first embodiment are as follows. The outer compartment 72 is filled with gas 74. In this preferred embodiment, an inert gas, such as argon, is filled in the compartment 72. The gas 74 insulates the heat generated by the lamp devices 30, so the heat will not be conducted directly to the outer tube 702. The outer tube 702 may be maintained at 45 degrees Celsius or less. Gas 74 also absorbs heat from inner tube 701.

The tubular shield 70 may be attached to the outer surface of the outer tube 702 by a protective film (not shown). In this case, when the lighting device 100 is broken on the floor and broken into pieces, the protective film can prevent the broken pieces from being separated from each other. The tubular shield 70 is applied with a fluorescent coating 75. The fluorescent coating 75 is applied to the surface of the outer tube 702 opposite the outer compartment 72. The light beams generated by the lamp devices 30 are emitted through the gas 74 to provide a light output similar to that of a typical fluorescent lighting fixture that can give a comfortable feeling to the user's eyes. Absorbed by the fluorescent coating 75 to generate other light beams that cooperate with the light beams emitted from the 30. The outer surface of the tubular shield 70 may be further processed into a rough surface that ensures smoother light output. The second preferred embodiment has the same advantages as the first preferred embodiment.

It should be noted that the fluorescent coating 75 may be omitted in other embodiments. The heat dissipation strip 10, the circuit board 20, the lamp units 30, the control modules 40, 50, and the input terminals 60 are integrated into an assembly, which is a tubular shield 70 during installation. Can be inserted in Accordingly, the installation of the energy saving lighting device 100 is simple. The fluorescent coating 75 may be applied to the surface of the inner tube 701 opposite the outer compartment 72. Therefore, the components of the circuit board 20 will not scratch the fluorescent coating 75 during installation. Since the heat dissipation strip 10 is suitably installed on the circuit board 20, the heat exchange area is increased, so that the heat dissipation capability of the lighting device 100 can be improved.

Light dispersion of a typical LED luminaire is limited to the projection angle of each LED, ie approximately 120 °. Since the circuit board 20 is flexible and consists of a tube, the lamp devices 30 mounted on the circuit board 20 provide 360 ° illumination. It should be noted that a printed circuit board (PCB) may be used in other embodiments. The PCB cannot be rolled up, but the four PCBs that mount the LEDs can be placed in square tubes and connected to each other to provide 360 ° illumination.

In summary, the advantages of the energy saving luminaire 100 according to the invention are as described below. The configuration of the double-tube tubular shield 70 provides thermal insulation from the inner tube 701 to the outer tube 702 of the heat generated by the lamp devices 30. 2 and 5, the tubular design of the heat dissipation strip 10 installed on the circuit board 20 increases the heat dissipation area, thereby ensuring efficient heat dissipation of the energy saving lighting fixture 100.

As shown in Fig. 6, the third preferred embodiment of the energy saving lighting fixture 100 (not shown) according to the present invention has a structure similar to that of the first embodiment. 6 illustrates the arrangement of lamp devices 30 on the circuit board 30 when laid flat on the plane. The main difference between this embodiment and the first embodiment is that the arrangement of the lamp devices 30 is modified and arranged in four rows on the circuit board 20. The lamp devices 30 in each row are arranged to be offset from the lamp devices 30 in the adjacent row along the circumferential direction of the tubular shield 70. The third preferred embodiment has the same advantages as the first preferred embodiment.

As shown in FIG. 7, the fourth preferred embodiment of the energy-saving lighting device 100 according to the present invention has a structure similar to the third embodiment. The main differences between this embodiment and the third embodiment are as follows. The lamp devices 30 are incandescent lamps. In this embodiment only one input terminal 60 is required. The input terminal 60 is mounted to the tubular shield 70 and is electrically connected to the control module 50. In order to increase the illuminance of the luminaire 100 at the end of the tubular shield 70, additional lamp devices 30 are mounted on the outer surface of the left control module 40. The fourth preferred embodiment has the same advantages as the first preferred embodiment.

8 and 9, the fifth preferred embodiment of the energy-saving lighting device 100 according to the present invention has a structure similar to the first embodiment. The main differences between this embodiment and the third embodiment are as follows. The luminaire 100 further comprises a washer 8 connected to the sleeve on the circuit board 20 in a close manner. The two end caps 81 are respectively provided at two both ends of the circuit board 20. Each of the end caps 81 extends from the end wall 811 to an end wall 811 adjacent to a corresponding one of the ends of the circuit board 20, and ends of the circuit board 20 in a tight manner. It has an annular wall 812 connected to a sleeve on a corresponding one of the two. Each of the end walls 811 of the end caps 81 has four spaced apart mounting holes 810, which are provided for heat dissipation, and are provided with a plurality of conductive wires of the circuit board 20. 22) extend through for electrical connection of the control modules 40, 50. Since the end caps 81 and the washers 8 are made of resin, the tube shape of the circuit board 20 can be maintained. Washers 8 and end caps 81 are mounted between the circuit board 20 and the tubular shield 70 in a tight manner to act as a cushion, so that the circuit board 20 vibrates the tubular shield 70. To prevent them from being scratched or scratched. The fifth preferred embodiment has the same advantages as the first preferred embodiment.

100: lighting fixture 70: tubular shield
71: internal compartment 72: external compartment
701: inner tube 702: outer tube
20: circuit board 30: lamp device
10: heat dissipation strip 101: strip body
102: basic segment 103: plate segment
11: heat dissipation fin 12: heat dissipation compartment
13: fixing hole 14: insulated colloid layer

Claims (10)

In order to form an outer compartment 72 between the inner tube 701 having the inner compartment 71 formed therein and the inner tube 701, the inner tube 701 is installed around the inner tube 701. A light transmissive tubular shield 70 comprising an outer tube 702 spaced apart from and having a double-tube structure; And
An energy saving luminaire (100) comprising a lamp assembly comprising at least one lamp device (30) installed to be fixed to the inner compartment (71) of the tubular shield (70). The method of claim 1,
The circuit board 20 further includes a circuit board 20 installed in the inner compartment 71 of the tubular shield 70, wherein the lamp assembly is disposed in a column form on the circuit board 20, a plurality of light emitting diodes Energy saving light fixture (100) comprising the lamp devices (30). The method of claim 1,
And a heat dissipation strip 10 installed on the circuit board 20 and in contact with the circuit board 20, and a tubular circuit board 20 installed in the inner compartment 71 of the tubular shield 70. And the lamp device (30) is connected to be fixed to an outer surface of the circuit board (20). The method of claim 3, wherein
The circuit board 20 is a flexible printed circuit board (20) energy-saving lighting fixture (100). The method of claim 4, wherein
Energy saving luminaire (100) further comprising a washer coupled to the circuit board (20) in a close manner. The method of claim 3, wherein
The heat dissipation strip 10 has a tubular strip body 101 having a heat dissipation compartment 12 formed therein, and a plurality of heat dissipation extending from the inner surface of the tubular strip body 101 toward the heat dissipation compartment 12. Energy saving luminaire 100 comprising pins 11. The method of claim 3, wherein
Energy saving type further comprises two control modules (40, 50) installed to connect both ends of the tubular circuit board 20, and at least one power terminal electrically connected to the control module (40, 50) Lighting fixtures 100. The method of claim 7, wherein
A heat dissipation strip 10 installed on the circuit board 20 and forming a heat dissipation compartment 12, and two spaced apart electrode pins 61, 62, respectively, and electrically connected to the control module 40, 50, respectively. Further comprising two input terminals 60 to be connected and two spaced connection walls 73 which are installed to seal the two ends of the tubular shield 70,
Two through holes 13 are formed in the spaced connection walls 73, and the electrode pins 61 and 62 of the input terminals 60 are formed in the through holes of the spaced connection walls 73. Respectively extending through 13, each of the control modules 40, 50 having heat dissipation holes 42, 52 in fluid communication with the heat dissipation compartment 12, each of the spaced connecting walls 73 being Energy saving lighting device 100 having a corresponding one of the heat dissipation holes 42, 52 of the control module 40, 50, and eventually a ventilation hole 732 in fluid communication with the heat dissipation compartment 12. ). The method of claim 1,
The tubular shield 70 further includes two spaced connecting walls 703 connecting the inner tube 701 and the outer tube 702 to each other to seal the two ends of the outer compartment 72. Energy-saving lighting fixtures 100. The method of claim 1,
A fluorescent coating is applied to the tubular shield 70, and the fluorescent coating is applied to the surface of one of the inner tube 701 and the outer tube 702 facing the outer compartment 72. Lighting fixtures 100.

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