LED Flashlight with Improved Heatsink
One electrical lead from an LED package is soldered to an inner electrically conductive member positioned and electrically isolated from an outer electrically conductive member by electrically insulating material while a second electrical lead and a neutral lead from the LED are soldered to the outer electrically conductive member so that heat is transferred from an LED die within the LED package to the outer electrically conductive member and then to a thermally conductive outer casing with a thermal path that minimizes thermal resistance.
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This application is a continuation-in-part application of U.S. Ser. No. 15/148,505, filed May 6, 2016, and is also a continuation-in-part application of U.S. Ser. No. 14/971,971, filed Dec. 16, 2015, which is a non-provisional application which claims priority from U.S. Ser. No. 62/095,733, filed Dec. 22, 2014, the disclosures of all of which are specifically incorporated by reference herein in their entireties.
FIELD OF THE INVENTIONThis application is in the field of flashlights that use surface mount light emitting diodes (LEDs) as light sources.
BACKGROUND OF THE INVENTIONIt is well known that LEDs give off heat during operation and that light output from an LED decreases with increasing LED die junction temperature. Accordingly, there is a well-recognized need for reducing LED die junction temperatures in LED flashlights to increase performance.
The present invention discloses and teaches a much improved LED lighting device, preferably with an outer metallic flashlight housing or barrel, which achieves superior performance through improved heat control of LED die junction temperature via an improved heatsink assembly.
SUMMARY OF THE INVENTIONThe present invention is generally directed to a lighting device, such as a flashlight, having heatsink technology in which one electrically conductive pad of an LED package is thermally and electrically bonded to an inner electrically conductive member which is positioned and electrically isolated from an outer electrically conductive member by electrically insulating material and a second electrically conductive pad and the thermal pad of the LED package are thermally and electrically bonded (such as by use of solder) to the outer electrically conductive member so that heat is transferred from an LED die within the LED package to the outer electrically conductive member and then to a thermally conductive outer casing with a thermal path in which thermal resistance is minimized.
Accordingly, it is a primary object of the present invention to provide improved heatsink technology.
This and further objects and advantages will be apparent to those skilled in the art in connection with the drawings and the detailed description of the invention set forth below.
In the Figures and the following detailed description, numerals indicate various physical components, elements or assemblies, with like numerals referring to like features throughout both the drawings and the description. Although the Figures are described in greater detail below, the following is a glossary of elements identified in the Figures.
1 flashlight
11 barrel of flashlight 1
11A shoulder of barrel 11
11AT top surface of shoulder 11A
11B nut
42 lip seal
51 tail cap
51 outer member of tail cap
58 spring
70 heatsink assembly
70A heatsink assembly with PCB held in core material
71 outer electrically conductive member of heatsink assembly 70
71C cavity formed in outer electrically conductive member 71
71K keyway in outer electrically conductive member 71
71OP opening in top surface 71T
71T top surface of outer electrically conductive member 71
72 core of an electrically insulating material of heatsink assembly 70
72A upper portion of core of an electrically insulating material of heatsink assembly 70A
72B lower portion of core of an electrically insulating material of heatsink assembly 70A
72E epoxy
72P passageway formed in core 72 into which epoxy 72E is flowed
73 inner electrically conductive member of heatsink assembly 70
73A upper portion of inner electrically conductive member of heatsink assembly 70A
73B lower portion of inner electrically conductive member of heatsink assembly 70A
73T top surface of inner electrically conductive member 73
74 thermal junction and electrical connection between LED package 120 and outer electrically conductive member 71
75 electrical connection between LED package 120 and inner electrically conductive member 73
76 thermal junction between outer electrically conductive member 71 and barrel 11 printed circuit board
77EAR ear for engaging PCB 77
77T trace on PCB 77
100 battery
120 LED package
121 LED die of LED package 120
122 silicon sub-mount of LED package 120
123 heat conductive material of LED package 120
124 wire bond of LED package 120
125 contact pad of LED package 120
126 contact pad of LED package 120
127 contact pad of LED package 120
128 outer casing of LED package 120
129 clear dome of LED package 120
173 electrical contact between 77EAR and 77T
402 heatsink
403 insulator
404 contact for supplying power to PCB
406 housing
407 insulator
408 contact for connecting PCB 111 to PCB 109
409 multilayered PCB
410 ring contact
411 PCB
426 first power connection
427 second power connection
428 star PCB
500 face cap
501 O-ring
502 lens
503 reflector
504 threaded nut
505 retaining ring
506 O-ring
508 O-ring
509 internal snap ring
510 actuator
511 switch port seal
512 switch
S1 solder
S1P solder point for solder S1
S2 solder
S2P solder point for solder S2
The present invention is generally applicable to many different types of lighting devices, an especially preferred embodiment of which is flashlights having an outer metallic casing, examples of which are described in U.S. Pat. Nos. 6,361,183 and 8,366,290, the disclosures of which are specifically incorporated by reference herein. Hereinafter, the invention will be illustrated by use of a flashlight without limiting the invention solely to such an embodiment.
Metallic flashlights have been using one or more light emitting diodes (“LEDs”) as a light source for a number of years. LEDs can be purchased from a number of suppliers, one example of which is Cree, and for purposes of illustration, Cree® XLamp® XP-G2 LEDs can be used as suitable LEDs.
An LED useful in the present invention is illustrated in
A heatsink assembly 70 according to the present invention has three main parts—an outer electrically conductive member 71 that is thermally conductive and which is mechanically connected to an outer casing of a lighting apparatus (e.g., a barrel 11 of a flashlight 1), a core 72 of an electrically insulating material which is held within a cavity formed in outer electrically conductive member 71 and one or more inner electrically conductive members 73 which is/are positioned and electrically isolated from outer electrically conductive member 71 by core 72. It is especially preferred that outer electrically conductive member 71 maintains thermal and mechanical connection to barrel 11 by a mechanical contact (such as a press fit, nut and thread connection, or some other mechanical means).
LED package 120 is thermally and electrically connected to heatsink assembly 70 so that LED package 120 is turned on when power from an electrical circuit is applied to outer electrically conductive member 71 and inner electrically conductive member 73.
The improved heatsink assemblies illustrated in
The present invention provides a direct efficient path to conduct heat away from an LED package to ambient air outside of a flashlight or any other lighting device such as a headlamp, lantern or spotlight, as well as all types of area lighting that utilize high powered LEDs as a light source. Other heatsinking methods produce thermal paths that include a large number of thermal junctions, some of which have poor thermal conductivity or high thermal resistance. Examples of prior art heatsinking methods are illustrated in
It is worth noting that the efficiency of the present invention can be increased or optimized, with the aid of the present disclosure, by increasing or maximizing the surface area exposure between the heatsink component of the heatsink assembly and the thermally and electrically conductive outer casing while also designing the heatsink component to have a sufficient mass to effectively and efficiently conduct heat between the heatsink assembly and the outer casing.
It is also worth noting that the outer casing, which is illustrated in the exemplary embodiments depicted in
Core 72 of the present invention is, in an especially preferred embodiment, molded with inner electrically conductive member 73 in place, to form a single assembly, which is inserted into a cavity 71C formed in outer electrically conductive member 71 so that passageway 72P is formed between core 72 and outer electrically conductive member 71 in cavity 72C which is then filled with epoxy 72E to securely hold core 72 within cavity 72C and precisely position top surface 73T in opening 71OP of top surface 71T so that top surface 73T of inner electrically conductive member 73 is accessible for soldering to a contact pad of LED package 120 to form electrical connection 75. Epoxy 72E may be comprised of an adhesive or material made from a class of synthetic thermosetting polymers containing epoxy groups which function as a glue or be made of any other material suitable for being flowed or injected into passageway 72P which will then harden and function to glue core 72 to outer electrically conductive member 71 within cavity 71C. It is especially desirable that outer electrically conductive member 71 include an additional mechanical means for holding core 72 within cavity 71C, one example of which is to include one or more keyways 71K that will form mechanical retention mechanisms once passageway 72P is filled with epoxy 72E.
After core 72 is secured within cavity 71C, heatsink assembly 70 is created by soldering a thermal pad and an electrically conductive pad of LED package 120 to top surface 71T of heatsink component 71. Commercially available LEDs typically have three or more pads (see, e.g.,
13A is for one pad whereas solder S2 in
Outer electrically conductive member 71 serves as the heatsink component of heatsink assembly 70 and its top surface 71T (see
Once heatsink assembly 70 is created, it can be press fit into a tube or barrel 11 as illustrated in
When heatsink assembly 70 is held by mechanical contact with barrel 11, a thermal path is created between the thermal pad and one contact pad of LED package 120 which is bonded to electrically conductive member 71 and barrel 11 which has a first thermal junction 74 between said thermal pad and one contact pad of LED package 120 and outer electrically conductive member 71 and a second thermal junction 76 between outer electrically conductive member 71 and barrel 11 (see
To demonstrate the lower thermal resistance obtainable by use of the heatsink technology of the present invention, tests were performed between different heat sink systems for use in a tube sized to accommodate a c-cell size battery. For each device under test (DUT), an LED package from the same family of LEDs was mounted on a heatsink system as noted below which was then pressed into a piece of aluminum of the same size and diameter to create the DUT, with the DUTs assembled as follows.
The UNI Module DUT used a heatsink system that corresponds to what is depicted in
The Starboard DUT used a heatsink system that corresponds to what is depicted in
The 0.070″ AL Molded DUT used a heatsink system that corresponds to what is depicted in
The Solid AL Molded DUT used a heatsink system that corresponds to what is depicted in
The DUTs were tested using the following testing methodology to obtain the test results set forth in Table 1:
-
- Measure LED solder point temperature {Tsp}. A precision thermocouple (Type J or Type K) is placed directly adjacent to LED package on the surface of the heatsink.
- DUT is powered from a digitally controlled power source at desired current level {ILED} and is recorded for later calculations
- DUT is powered on long enough for solder point temperature to stabilize (usually 30 to 45 minutes). Temperature is measured and logged using precision data acquisition instrument. Once peak temperature is observed, it is recorded as {Tsp}
- Measure LED Forward Voltage {Vf} at desired current level {ILED} when peak {Tsp} is observed. The LED Voltage {Vf} is measured using a precision volt meter connected directly to the LED solder pads
- Total LED Power Dissipation {Pd} is calculated using equation 1. LED current {ILED} multiplied by measured LED Forward Voltage {Vf}.
- Calculate thermal resistance {ΘRth} using equation 2. This is the total thermal resistance of the heat sink and flashlight barrel, from LED solder point {Tsp} to ambient air {Tamb}
- Obtain manufacturer's thermal resistance {ΘRthLED} specification for the LED family being used. In this case, the Cree XM-L2 is 2.5° C./W.
- Calculate LED junction temperature {Tj} using equation 3. This is the temperature of LED die, also called LED junction.
Pd=ILED*Vf 1.
ΘRth=(Tsp−Tamb)/Pd 2.
Tj=(Pd*ΘRthLED)+Tsp 3.
Definitions of Variables and Constants:
- ΘRth=Calculated Thermal resistance of heat sink (overall thermal resistance, from Tsp to ambient air Tamb) [° C./W]
- Tsp=Solder point temperature (measured directly adjacent to LED substrate) [° C.] using thermocouple
- Tamb=Ambient air temperature [° C.]
- Pd=Total calculated dissipated power [W]
- ILED=LED drive current [A]
- Vf=LED forward voltage [V]
- Tj=Calculated LED Junction temperature [° C.]
- ΘRthLED=Manufacturer specified thermal resistance of LED family [° C./W] XM-L2 LED: 2.5° C./W
In calculating the results set forth in Table 1, it was assumed that 100% of total power is dissipated as heat. This is the absolute worst case scenario because, in a real world application, only about 60-70% of the total power is dissipated as heat, while the remaining 30-40% is converted to photon energy (light), but it's nearly impossible to know the precise efficacy (ability to convert electrical power to photon energy) of each LED, so 100% power dissipation was used for the worst case scenario.
It should also be noted that tests were made on a heatsink system that corresponds to what is depicted in
While the invention has been described herein with reference to certain preferred embodiments, those embodiments have been presented by way of example only, and not to limit the scope of the invention. Additional embodiments will be obvious to those skilled in the art having the benefit of this detailed description.
Accordingly, still further changes and modifications in the actual concepts descried herein can readily be made without departing from the spirit and scope of the disclosed inventions as defined by the following claims.
Claims
1. A lighting apparatus, comprising:
- an outer casing that is thermally conductive;
- a light emitting diode (“LED”) package contained within the outer casing, said LED package comprising: a substrate; an LED die held by the substrate, said LED die configured to emit light outwardly from a front surface of the LED package; a first electrically conductive pad; a second electrically conductive pad; and a thermal pad configured for removing heat from the LED die to outside of the LED package;
- wherein the first and second electrically conductive pads are configured to provide power to cause the LED die to emit light;
- wherein the first and second electrically conductive pads and the thermal pad are located on a rear surface of the LED package opposite from the LED die; and
- a heatsink assembly held within the outer casing, said heatsink assembly comprising: an outer electrically conductive member that is thermally conductive and which is mechanically connected to the outer casing; a core of an electrically insulating material which is held within a cavity formed in the outer electrically conductive member; and an inner electrically conductive member which is positioned and electrically isolated from the outer electrically conductive member by the core;
- wherein the first electrically conductive pad and the thermal pad are thermally and electrically bonded to a first top surface of the outer electrically conductive member without use of a printed circuit board and the second electrically conductive pad is electrically bonded to a second top surface of the inner electrically conductive member.
2. The lighting apparatus of claim 1, wherein the first electrically conductive pad and the thermal pad are soldered to the first top surface and the second electrically conductive pad member is soldered to the second top surface.
3. The lighting apparatus of claim 1, wherein the core and the inner electrically conductive member are comprised of a single molded assembly.
4. The lighting apparatus of claim 1, wherein the core is configured to form a passageway between the core and the outer electrically conductive member when the core is inserted into the cavity.
5. The lighting apparatus of claim 4, further comprising an epoxy held within the passageway.
6. The lighting apparatus of claim 5, further comprising a mechanical means for holding the core within the cavity.
7. The lighting apparatus of claim 5, further comprising a printed circuit board (“PCB”) held within the core in a vertical orientation with respect to the first top surface.
8. The lighting apparatus of claim 1, wherein the lighting apparatus is comprised of a flashlight and the outer casing is comprised of a flashlight barrel.
9. A method for creating a flashlight mode with increased lumens or with increased on-time, comprising:
- inserting a core which holds an inner electrically conductive member into a cavity formed in an outer electrically conductive member so that a second top surface of the inner electrically conductive member is positioned within an opening in a first top surface of the outer electrically conductive member and the inner and outer electrically conductive members are electrically isolated from one another;
- soldering both a first electrically conductive pad and a thermal pad of a light emitting diode (“LED”) package to the first top surface without use of a printed circuit board as well as soldering a second electrically conductive pad of the LED package to the second top surface to form a heatsink assembly, wherein said LED package is comprised of the first electrically conductive pad, the second electrically conductive pad and the thermal pad, wherein the first and second electrically conductive pads are configured to provide power to cause a die within the LED package to emit light outwardly from a front surface of the LED package, wherein the thermal pad is configured for removing heat from the LED package, and wherein the first and second electrically conductive pads and the thermal pad are located on a rear surface of the LED package opposite from the die; and
- inserting the heat sink assembly into a flashlight barrel so that the heat sink assembly is held by mechanical contact with the barrel and a thermal path is created between the flashlight barrel and the first electrically conductive pad and the thermal pad of the LED package which is only interrupted by a first thermal junction between the flashlight barrel and the outer electrically conductive member and a second thermal junction between the outer electrically conductive member and the first electrically conductive pad and the thermal pad of said each LED package;
- wherein providing power to the first and the second electrically conductive pads of the LED package cause the die within the LED package to emit light.
10. The method of claim 9, further comprising the step of putting epoxy into a passageway formed between the core and the outer electrically conductive member after the core is inserted into the cavity.
11. The method of claim 10, wherein the epoxy creates a mechanical means for holding the core within the cavity.
Type: Application
Filed: Jun 14, 2016
Publication Date: Dec 8, 2016
Applicant: Mag Instrument, Inc. (Ontario, CA)
Inventor: Anthony Maglica (Ontario, CA)
Application Number: 15/182,396