Patent Grant
8956017
This application is based upon and claims the benefit of priority from the prior Japanese Patent Application No. 2011-042629, filed on Feb. 28, 2011; the entire contents of which are incorporated herein by reference.
Embodiments described herein relate generally to a lighting apparatus.
A structure of an illumination apparatus having solid state light emitting devices such as LED (Light Emitting Diode), needs good heat dissipation for high performance like luminance and reliable.
In general, according to one embodiment, a lighting apparatus includes a case, a power source unit, and a light emitting unit. The power source unit is contained in an interior of the case. A light emitting unit is provided on the power source unit. The light emitting unit includes a light emitting device configured to emit light by a current being supplied from the power source unit. The case has a side portion provided around a first axis parallel to a direction from the power source unit toward the light emitting unit. The side portion is provided around the power source unit. The side portion has a first portion and a second portion disposed around a central axis parallel to the first axis. The central axis passes through a center of an upper end of the case when viewed along the first axis. The first portion has a long distance to the central axis. The second portion has a short distance to the central axis. An end portion of an inner surface of the second portion is configured to have at least one selected from a portion perpendicular to the central axis and a portion having a recessed configuration with respect to the central axis when the inner surface is cut by a cross-section perpendicular to the central axis, the inner surface being configured to oppose the power source unit.
Embodiments will now be described with reference to the drawings.
The drawings are schematic or conceptual; and the relationships between the thicknesses and the widths of portions, the proportions of sizes among portions, etc., are not necessarily the same as the actual values thereof. Further, the dimensions and the proportions may be illustrated differently among the drawings, even for identical portions.
In the specification and the drawings of the application, components similar to those described in regard to a drawing thereinabove are marked with like reference numerals, and a detailed description is omitted as appropriate.
As illustrated in
The case 10 functions to dissipate heat generated at, for example, at least one selected from the power source unit 30 and the light emitting unit 20. The case 10 includes a material having high thermal conductivity. The case 10 includes, for example, a metal. The case 10 includes, for example, aluminum, etc.
The power source unit 30 includes a power source substrate 31 and an electrical part 32. The electrical part 32 is mounted on a major surface 31a of the power source substrate 31. The electrical part 32 includes, for example, a part configured to control the current supplied from the power source unit 30 toward the light emitting device 21. Other than the electrical part 32, electrical parts may be mounted on the surface of the power source substrate 31 on the side opposite to the major surface 31a.
The light emitting unit 20 further includes, for example, a light source substrate 22, a light source heat dissipation plate 23, and a wavelength conversion layer 24. The light emitting device 21 is mounted on the light source substrate 22. Specifically, the light emitting device 21 is provided on the upper surface of the light source substrate 22. The light source heat dissipation plate 23 is provided on the lower surface (the surface on the power source unit 30 side) of the light source substrate 22. The light source heat dissipation plate 23 dissipates the heat generated at the light emitting device 21. The wavelength conversion layer 24 covers at least a portion of the light emitting device 21. The wavelength conversion layer 24 absorbs at least a portion of the light emitted from the light emitting device 21 and emits light of a wavelength different from the wavelength of the emitted light. The wavelength conversion layer 24 includes, for example, a fluorescer layer.
The light emitting device 21 includes, for example, a semiconductor light emitting device. Specifically, the light emitting device 21 includes an LED. The light emitting device 21 emits, for example, light (an emitted light) of a relatively short wavelength. The wavelength conversion layer 24 absorbs this light and converts this light into light of a long wavelength. Thereby, the light emitting unit 20 radiates, for example, white light. The white light includes various white light that is violet-tinted, bluish, greenish, yellowish, reddish, etc.
The lighting apparatus 110 is, for example, an LED electric bulb.
As illustrated in
The insulating member 40 is provided between the case 10 and the power source unit 30. The insulating member 40 electrically isolates the case 10 from the power source unit 30.
The sealing resin 43 is filled into the space between the insulating member 40 and the power source unit 30. The sealing resin 43 is, for example, a potting resin. The sealing resin 43 may include an insulative material. The sealing resin 43 may include, for example, a material having high thermal conductivity. Thereby, the heat generated at the power source unit 30 can be efficiently conducted to the case 10. The sealing resin 43 may be provided if necessary and can be omitted in some cases.
The base cap 50 is connected to a terminal included in the power source unit 30 and conducts the necessary current from the outside to the power source unit 30. The base cap 50 functions to fix the lighting apparatus 110 to another appliance.
The globe 60 covers at least a portion of the light emitting unit 20. The globe 60 can control, for example, the light distribution angle of the light radiated from the light emitting unit 20 by modifying the path of the light. At least a portion of the lower end of the globe 60 contacts an upper end 10a of the case 10. The lower end of the globe 60 is bonded to the upper end 10a of the case 10.
Herein, an axis parallel to the direction from the power source unit 30 toward the light emitting unit 20 is taken as a Z axis (a first axis). One axis perpendicular to the Z axis is taken as an X axis. An axis perpendicular to the Z axis and the X axis is taken as a Y axis.
The case 10 includes a side portion 10s. The side portion 10s is provided around the Z axis and around the power source unit 30.
As illustrated in
The side portion 10s includes a first portion 11 and a second portion 12 that are disposed around the central axis Z1. The distance between the first portion 11 and the central axis Z1 is long. The distance between the second portion 12 and the central axis Z1 is short. In other words, the distance between the second portion 12 and the central axis Z1 is shorter than the distance between the first portion 11 and the central axis Z1.
In other words, the first portion 11 is an outer portion of the side portion 10s; and the second portion 12 is a portion of the side portion 10s protruding inward. The second portion 12 is a portion proximal to the central axis Z1. In this example, the first portion 11 opposes the second portion 12 along the X-axis direction.
For example, the first portion 11 is a thin portion of the side portion 10s; and the second portion 12 is a thick portion of the side portion 10s.
An end portion 12e of an inner surface 12s of the second portion 12 opposing the power source unit 30 when the inner surface 12s is cut by a cross-section (an X-Y plane) perpendicular to the central axis Z1 has at least one selected from a portion perpendicular to the central axis Z1 and a portion having a recessed configuration with respect to the central axis Z1. In this example, the end portion 12e of the inner surface 12s when cut by the cross-section (the X-Y plane) is perpendicular to the central axis Z1. In this example, the end portion 12e of the inner surface 12s recited above is parallel to, for example, the Y axis.
In this example, the end portion 12e of the inner surface 12s of the second portion 12 (the end portion when the inner surface 12s is cut by the X-Y plane) has a portion parallel to the major surface 31a of the power source substrate 31. In this example, the thickness of the second portion 12 is thicker than the thickness of the first portion 11.
Thus, the side portion 10s of the case 10 that has the heat dissipation function of the lighting apparatus 110 has the second portion 12 that is proximal to the central axis Z1. For example, the second portion 12 is more proximal to the power source unit 30 than is the first portion 11. Thereby, the heat generated at the power source unit 30 is efficiently conducted to the second portion 12. Thereby, a lighting apparatus having better heat dissipation can be provided.
The light emitting unit 20 is thermally coupled to at least a portion of the second portion 12 of the case 10.
Specifically, as illustrated in
The surface area of the portion where the second portion 12 is thermally coupled to the light emitting unit 20 is greater than the surface area of the portion where the first portion 11 is thermally coupled to the light emitting unit 20 because the second portion 12 is more proximal to the central axis Z1 than is the first portion 11. By providing the second portion 12, the surface area of the path of the heat conduction between the case 10 and the light emitting unit 20 increases. Thereby, the heat generated at the light emitting device 21 is efficiently conducted to the case 10. Thereby, the heat dissipation improves further.
Also, by providing the second portion 12, the spacing between the second portion 12 and the power source unit 30 is smaller than in the case where the second portion 12 is not provided. Therefore, for example, the space between the insulating member 40 and the power source unit 30 in the region between the second portion 12 and the power source unit 30 decreases. Thereby, the amount of the sealing resin 43 can be reduced in the case where the sealing resin 43 is provided. Therefore, the cost can be reduced. In the case where aluminum and the like are used as the case 10, the density of the sealing resin 43 is higher than the density of the case 10. As recited above, a lighter lighting apparatus 110 is possible by reducing the amount of the sealing resin 43.
As illustrated in
Therefore, the heat generated at the power source unit 30 is not easily conducted efficiently to the side portion 10s. Further, the surface area where the light source substrate 22 contacts the side portion 10s of the case 10 is small. Therefore, the heat generated at the light emitting device 21 is not easily conducted efficiently to the case 10 via the light source substrate 22. Further, the space between the side portion 10s and the power source unit 30 is large. Therefore, for example, the amount of the sealing resin 43 is large in the case where the sealing resin 43 is provided.
As illustrated in
Thus, in an LED electric bulb, a structure is conceivable in which the screw retaining portion 18 is provided in a portion of the side portion 10s of the case 10. The screw retaining portion 18 is designed with the approach of reducing the volume of the screw retaining portion 18 as much as possible because it is sufficient for the screw retaining portion 18 to function, for example, to fix the light emitting unit 20. In other words, the screw retaining portion 18 is designed to increase the space of the interior of the case 10 as much as possible to increase the margin of the design of the power source unit 30 contained in the interior of the case 10. Therefore, as in the second reference example, the surface of the screw retaining portion 18 opposing the power source unit 30 is designed to have the protruding configuration.
In the lighting apparatus 110 according to the embodiment, the case 10 is designed with an approach that is entirely different from the approach recited above. In other words, the space of the interior of the case 10 is not large. In the embodiment, the case 10 is designed to reduce, for example, the space between the case 10 and the power source unit 30 (and the space between the insulating member 40 and the power source unit 30). In the embodiment, the end portion 12e of the inner surface 12s of the second portion 12 has, for example, the portion perpendicular to the central axis Z1. As described below, the end portion 12e of the inner surface 12s may have a portion having a recessed configuration.
As in the power source substrate 31 and the like, the power source unit 30 includes a member having a surface perpendicular to the central axis Z1. For example, at least a portion of the inner surface 12s of the second portion 12 is provided along this member. In the lighting apparatus 110 as illustrated in
Thereby, the heat generated at the power source unit 30 is efficiently conducted to the side portion 10s. Further, the light emitting unit 20 is thermally coupled to (e.g., contacts) the side portion 10s of the case 10 at the second portion 12 which has the large surface area. Because the coupling surface area is large, the heat generated at the light emitting device 21 is efficiently conducted to the case 10 via the light source substrate 22. For example, in the lighting apparatus 110 according to the embodiment, the temperature of the light source substrate 22 can be as much as 7° C. lower than the lighting apparatus 119a of the first reference example.
Also, the lighting apparatus 110 can be lighter with lower costs by reducing the space between the side portion 10s and the power source unit 30 and reducing the amount of the sealing resin 43.
Thus, in the embodiment, the second portion 12 is provided based on a concept that is different from conventional design concepts of the screw retaining portion 18 and the like and extensions of such conventional design concepts. Thereby, the thermal conductivity between the case 10 and at least one selected from the power source unit 30 and the light emitting unit 20 increases. Thereby, a lighting apparatus having better heat dissipation can be provided. Further, the amount of the sealing resin 43 can be reduced in the case where the sealing resin 43 is provided.
In the embodiment, a fixation portion configured to fix the light emitting unit 20 to the second portion 12 may be further provided in the second portion 12. This fixation portion includes, for example, a groove for a helix for screw retention. The fixation portion includes a protrusion, a groove, and the like configured to mesh with the light emitting unit 20. The light emitting unit 20 may be bonded to the second portion 12 (the case 10) by, for example, a bonding member having a high thermal conductivity.
In the lighting apparatus 110 of this specific example as illustrated in
The protruding portion 40a functions to electrically insulate the case 10 from the base cap 50. The length along the Z axis of the protruding portion 40a is set to be not less than the distance necessary to electrically insulate the case 10 from the base cap 50. Thereby, the electrical insulation can be ensured.
Such a configuration is obtained by, for example, integrally forming the insulating member 40 with the case 10. Such a formation may include, for example, insert molding. The existence of air between the case 10 and the insulating member 40 is suppressed by using the insert molding. Thereby, the thermal conductivity between the case 10 and the insulating member 40 increases and the heat dissipation improves. Also, it is advantageous that assembly processes of the parts can be omitted.
However, the embodiment is not limited thereto. The methods for forming the case 10 and the insulating member 40 are arbitrary. The protruding portion 40a may be provided if necessary and may be omitted.
In the lighting apparatus 111, the side portion 10s of the case 10 further includes a third portion 13 disposed around the central axis Z1 when viewed along the Z axis in addition to the first portion 11 and the second portion 12 recited above. The distance between the third portion 13 and the central axis Z1 is shorter than the distance between the first portion 11 and the central axis Z1. An inner surface 13s of the third portion 13 opposing the power source unit 30 has a protruding configuration protruding inward from the outside. The light emitting unit 20 can be thermally coupled to at least a portion of the third portion 13 of the case 10. For example, the light source heat dissipation plate 23 contacts the third portion 13.
By providing the third portion 13, a lighting apparatus having even better heat dissipation can be provided. Also, the amount of the sealing resin 43 can be reduced in the case where the sealing resin 43 is provided.
In this example, an end portion 13e of the inner surface 13s of the third portion 13 when the inner surface 13s is cut by a cross-section (the X-Y plane) has a portion perpendicular to the central axis Z1. A portion of the end portion 13e of the inner surface 13s is parallel to, for example, the X axis; and another portion is parallel to, for example, the Y axis. In this example, the end portion 13e of the inner surface 13s of the third portion 13 has a portion parallel to the major surface 31a of the power source substrate 31. The thickness of the third portion 13 is thicker than the thickness of the first portion 11.
In the lighting apparatus 112 as well, the side portion 10s of the case 10 has the second portion 12. In this example, the second portion 12 has multiple inner trenches 14. The multiple inner trenches 14 extend along the central axis Z1 (or the Z axis). At least a portion of the multiple inner trenches 14 recedes outward from the inner side of the side portion 10s.
By providing the multiple inner trenches 14, the heat dissipation improves further. By providing the multiple inner trenches 14, the case 10 is lighter.
In this example, the multiple inner trenches 14 have walls extending along a second axis (e.g., the X axis) perpendicular to the central axis Z1. For example, the multiple inner trenches 14 include walls parallel to the Z-X plane. The multiple inner trenches 14 are juxtaposed along the Y axis. Thereby, in the case where the multiple inner trenches 14 are provided, the manufacturing is easier. The case 10 is manufactured by, for example, die casting. In such a case, the manufacturing of the multiple inner trenches 14 of the configuration recited above is simpler and the productivity is higher than those of the case where the multiple inner trenches 14 are disposed in, for example, a radial configuration.
The multiple inner trenches 14 may not be provided in the uppermost portion of the second portion 12. In other words, the uppermost portion of the second portion 12 may be a thick portion; and the multiple inner trenches 14 may be provided lower than the thick portion in the second portion 12. Thereby, for example, the contact surface area between the thick portion of the second portion 12 and the light emitting unit 20 (e.g., the light source heat dissipation plate 23) can be large; and good heat dissipation is obtained.
In the lighting apparatus 113 as illustrated in
The multiple outer trenches 15 function as, for example, heat dissipation fins. Thereby, the heat dissipation improves further. Also, by providing multiple inner trenches 14, the case 10 may be lighter.
In this example, at least a portion of the multiple outer trenches 15 extends along the central axis Z1. Specifically, the multiple outer trenches 15 have walls extending along the second axis (e.g., the X axis) perpendicular to the central axis Z1. Thereby, the manufacturing is easier in the case where the multiple outer trenches 15 are provided. The case 10 is manufactured by, for example, die casting. In such a case, the manufacturing of the multiple outer trenches 15 of the configuration recited above is simple and the productivity is high.
The second portion 12 has a planar portion 12a that extends in a plane perpendicular to the central axis Z1 to oppose the light emitting unit 20 between the light emitting unit 20 and the multiple outer trenches 15, i.e., at the uppermost portion that is thermally coupled to the light emitting unit 20. The multiple outer trenches 15 are provided on the lower side of the planar portion 12a and are not provided in the uppermost portion. Thereby, the contact surface area between the planar portion 12a and the light emitting unit 20 (e.g., the light source heat dissipation plate 23) can be large; and good heat dissipation is obtained.
The inner trench 14 and the outer trench 15 recited above may be provided in the third portion 13.
As illustrated in
In a lighting apparatus 115 according to the embodiment as illustrated in
In the lighting apparatus 116 according to the embodiment as illustrated in
A recess (an insulating member notch 40h) is provided in the insulating member 40 to match the configuration of the case notch 12h. The insulating member notch 40h is a portion that recedes downward. The insulating member notch 40h communicates with the case notch 12h. The insulating member notch 40h is provided, for example, to be juxtaposed with the position where the case notch 12h is provided in the X-Y plane. Thereby, the insulating member notch 40h communicates with the case notch 12h.
For example, the configurations of the case notch 12h and the insulating member notch 40h open upward from below when viewed along the direction outward from inside the case 10. The insulating unit notch 40h has a configuration corresponding to the width and the depth of the case notch 12h. The outline of the insulating unit notch 40h is formed to match the outline of the case notch 12h.
The case notch 12h and the insulating member notch 40h are used as a gap to insert the tip of a nozzle to dispense the sealing resin 43 when filling the sealing resin 43 between, for example, the case 10 and the power source unit 30 (specifically, between the insulating member 40 and the power source unit 30). By the case notch 12h and the insulating member notch 40h having the configurations that open upward from below, the tip of the nozzle can be easily inserted into this portion.
Thus, the productivity of the process of filling the sealing resin 43 improves by providing the case notch 12h of the inner surface 12s of the second portion 12 at the uppermost portion of the inner surface 12s and by providing the insulating member notch 40h in the insulating member 40.
As illustrated in
In this example, the recess 10b is a trench extending along the Z axis. The protruding portion 40b of the insulating member 40 is filled into this trench. The protruding portion 40b functions as an anchor. Thereby, the contact surface area between the case 10 and the insulating member 40 increases; and, for example, the thermal conductivity improves.
When performing the insert molding of the insulating member 40 with the case 10, there are cases where the resin of the insulating member 40 may contract and deform when curing; and thereby, the adhesion between the case 10 and the insulating member 40 may be poor. Conversely, as in this example, the adhesion between the case 10 and the insulating member 40 improves by providing the trench (the recess 10b) in the case 10 and by filling the protruding portion 40b, which is used to form the anchor, into this trench. The poor adhesion recited above can be suppressed also by the protruding portion 40a described in regard to
In the lighting apparatus 118 according to the embodiment as illustrated in
By the inner surface 12s being tilted with respect to the central axis Z1, for example, the case 10 is easier to manufacture (e.g., when manufacturing the case 10 by die casting).
In such a case as well, the end portion 12e of the inner surface 12s has a portion perpendicular to the central axis Z1 (e.g., a portion along the Y axis). Also, the end portion 12e of the inner surface 12s when the inner surface 12s is cut by the X-Y plane has a portion parallel to the major surface 31a of the power source substrate 31 (a portion along the Y axis).
In the lighting apparatus 118a according to the embodiment as illustrated in
In such a case as well, the second portion 12 is more proximal to the power source unit 30 than is the first portion 11. The surface area of the thermal coupling of the case 10 with the light emitting unit 20 increases at the second portion 12. Thereby, the heat dissipation can be improved. Also, the amount of the sealing resin 43 can be reduced when providing the sealing resin 43.
According to the embodiment, a lighting apparatus having better heat dissipation is provided.
Hereinabove, exemplary embodiments of the invention are described with reference to specific examples. However, the embodiments of the invention are not limited to these specific examples. For example, one skilled in the art may similarly practice the invention by appropriately selecting specific configurations of components included in lighting apparatuses such as cases, side portions, light emitting units, light emitting devices, light source substrates, light source heat dissipation plates, wavelength conversion layers, power source units, power source substrates, electrical parts, insulating members, sealing resins, base caps, globes, etc., from known art; and such practice is included in the scope of the invention to the extent that similar effects are obtained.
Moreover, all lighting apparatuses practicable by an appropriate design modification by one skilled in the art based on the lighting apparatuses described above as embodiments of the invention also are within the scope of the invention to the extent that the spirit of the invention is included.
While certain embodiments have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel embodiments described herein may be embodied in a variety of other forms; furthermore, various omissions, substitutions and changes in the form of the embodiments described herein may be made without departing from the spirit of the inventions. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the invention.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2011-042629 | Feb 2011 | JP | national |
| Number | Name | Date | Kind |
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| 6794801 | Yasuda et al. | Sep 2004 | B2 |
| D589175 | Xue | Mar 2009 | S |
| D664685 | Carroll et al. | Jul 2012 | S |
| 20090175041 | Yuen et al. | Jul 2009 | A1 |
| 20100295436 | Horng et al. | Nov 2010 | A1 |
| 20120161627 | Chang et al. | Jun 2012 | A1 |
| Number | Date | Country |
|---|---|---|
| 102022656 | Apr 2011 | CN |
| 2009059707 | Mar 2009 | JP |
| 2010-56059 | Mar 2010 | JP |
| 2010-129414 | Jun 2010 | JP |
| 2011-124182 | Jun 2011 | JP |
| Entry |
|---|
| English machine translation of Applicant disclosed prior art: JP 2011-124182. |
| Japanese Office Action Issued Jan. 28, 2013 in Patent Application No. 2011-042629 (with English translation). |
| Combined Office Action and Search Report issued Jan. 23, 2014 in Chinese patent Application No. 201210046675.0 (with English translation). |
| Combined Chinese Office Action and Search Report issued Sep. 18, 2014, in Chinese Patent Application No. 201210046675.0 with English translation. |
| Number | Date | Country | |
|---|---|---|---|
| 20120218743 A1 | Aug 2012 | US |
