Walterk
Enlightened
Huygens Ultimate - 2.140.000 candela Led light
The world's brightest single Led light and the first to break the 1.800.000 candela mark.
That means, with a 3Watt led and 4xAA batterie, it enlights any object at 1.342 metres / 1.472 yards with 1 Lux.
Edit: Measured 214 lux at 100 metres, equals 2.140.000 candela, enlights an object at 1.460 metres with 1 lux.
Meet the Huygens Ultimate:
Testing
Outdoor1
Outdoor2
Outdoor3
Facts and figures:
Range: 1.342 metres
Peak beam intensity: 1.800.000 candela
Lumen: 200 (losses in optics not accounted for )
Led: 3 Watt Led; Cree XRE R2 WH EZ900 at 2,3 Amp
Driver: 2.5 Ampere DIW-Diver (effective 2.3A)
Wattage: 9 Watt = 4.0V x 2.3A
Battery's: 4 x AA 1.4v Nimh Eneloop 2000mah
Heatsink: Passive copper heatsink
Runtime: approx. 40 minutes.
Dimensions: Length 63cm x Width 28cm x Heigth 32cm.
Weight: 8,8 kg
Material: Stainless Steel 304
Features: Focusable, the beam angle (and thus intensity ) can be adjusted, tripod-mount, bezel-stand, lanyard.
Collimator lens: Aspheric, diameter 75mm, aperture 50mm, back focal length 40mm, f-number 0.55 (Thorlabs ACl 7560 ),viewangle 84 degrees.
Main lens: Plano-convex, diameter. 262mm, aperture 250mm, back focal length 500mm, f-number 1.9 (Estimated ), (found magnifying glass ) viewangle 38 degrees.
Distance between both lenses: 440mm (plain surface to plain surface)
Distance between Led and first lens: 8 -10 -15-21mm (top of dome to plain surface lens ) :
08mm Needle:
Beam angle 0.5 degree, spotsize at 50 meter 0.4x0.4m
1.8000.000 candela, means 1 lux at 1.342 metres distance, 20 lux at 300 metres distance.
10mm Fine spot:
Beam angle 0.7 degree, 1.600.000 candela, spotsize at 50 meter Dia.0.6m
1.600.000 candela, means 1 lux at 1.265 lux at metres distance, 20 lux at 283 metres distance.
15mm Spot with hotspot:
Beam angle 2.8 degree, 375.000 candela, spotsize at 50 meter Dia. 2.3m
375.000 candela, means 1 lux at 612 metres distance, 20 lux at 137 metres distance.
25mm Flood:
Beam angle 4,7 degree, 50.000candela, spotsize at 50 meter Dia. 4.13m
50.000 candela, means 1 lux at 224 metres distance, 20 lux at 50 metres distance.
(To get consistent Lux measurements a distance of at least 25 meter was needed.)
Introduction:
Reading inspiring threads at CPF, I thought, why couldnt I do what they can...? Naturally I bought some stuff that didn't work, call it Research and Development, but I learned a lot and it was a great pass time.
I read about materials for heatsinking and heatpipes, white led tests, aspherics, data-sheets, focal lenghts, f-numbers, telescopes and beam expanders, drivers and batterys. In my search I found more explicite help from several members that answered some questions, and I thank them for their helpfulness. I like to share my findings, as the best members of CPF do. As soon as I understood how Led's work with aspherics, I had the concept thought over, it took me some longer to have the details right. It was good hobby-time, and am satisfied with the result. For me the fun is not only in the result, but in finding my way to solutions.
This might be the World's most powerful single Led-light at this moment, but only because I don't know of any equivalent beast.
How it works:
The first lens, close to the Led, captures most of the light sent out by the Led. Due to its short focal length, it captures a very reasonable part of the emitted lumen.
This light is dan forwarded, and narrowed down, to enlight the full diameter of the big lens.
This big lens magnifies the brightness of the Led for every square mm2 of its surface, which is accountable for the throw.
Due to its long focal length the outgoing beam has a somewhat narrow angle.
This double lens set-up uses the principle of a beam expander as used in Laserlight technology and eyepieces.
A single lens would be more efficient for throw, but worse in lumen, in practice I find this the best of both and most cost efficient in case you have a large lens at hand and want to utilize it. The beamangle is a result of the two lenses, in combination with the size of the led's light-emitting surface.
I used the 5 dollar Cree XRE R2, for two characteristics:
Because the light-emitting surface, the 'die', is small, the die has the highest relative surface-brightness (intensity) of commonly available and known Led's.
It projects its light in a smaller, more condensed cone than other led's, sending more Lumen in the first lens.
Naturally, in time I will ugrade this Led once there is a Led that's even more sweet.
The Led-base is sanded down to 0.1mm to minimize thermal-path to the heatsink, -thanx to Ra- pressed to the heatsink with thermal paste.
The well ventilated heatsink, copper for best properties, open structure for best airflow, a bit over-dimensioned to be on the safe side.
It still gets warm so I should ad a fan to it.
I used AA-batteries as I wanted it to be powered by batterys people are familiar with. I could have done with a single and smaller battery of other chemistry.
Direct drive give's higer Lux-readings, but readings would fall rapidly after a few minutes as the voltage of the batteries get lower. That's why I choose to use a driver, so the light output is constant for a longer time.
More technical info:
For lumen, lux, candela see Wiki.
Optics theory - fundamentals on reflectors/optics
Formula for calculating throw using aspheric lens
Main inspirations:
SST-50 homemade spotlight - EasyB's plain, simple, effective using a fresnel lens
Fat Needle 400 - long throw, thin beam - Dr.Jones's testbench
Data Bank 70 - Data's techno multi led thrower
Maxablaster - Ra's engineered thrower
HID-Killer: Adaptor for 1xCree light - Long John's first to use pre-collimator
How to make a Cree Throw - Newbie's mother of aspheric flashlights
Huygens Wiki - This light is named after Huygens, a Dutch scientist from the 16th century, kown for-among others- his telescopes. He enhanced the principle of using two converging lenses in row to reach collimating, a simple assembly for getting a short focal-length and a narrow beam. Quite useful for our use with Led's and aspheric condensor lenses. Huygens build tubeless telescopes up to 62 metres length, to be the first to tell you Saturn has a ring around it. The same principle is still used in telescopes and microscopes and binoculairs.
The tubeless design, and his urge to improve, with hands-on experiments, appealed to me, hence the name for this steampunk-tech-style.
The world's brightest single Led light and the first to break the 1.800.000 candela mark.
That means, with a 3Watt led and 4xAA batterie, it enlights any object at 1.342 metres / 1.472 yards with 1 Lux.
Edit: Measured 214 lux at 100 metres, equals 2.140.000 candela, enlights an object at 1.460 metres with 1 lux.
Meet the Huygens Ultimate:
Testing
Outdoor1
Outdoor2
Outdoor3
Facts and figures:
Range: 1.342 metres
Peak beam intensity: 1.800.000 candela
Lumen: 200 (losses in optics not accounted for )
Led: 3 Watt Led; Cree XRE R2 WH EZ900 at 2,3 Amp
Driver: 2.5 Ampere DIW-Diver (effective 2.3A)
Wattage: 9 Watt = 4.0V x 2.3A
Battery's: 4 x AA 1.4v Nimh Eneloop 2000mah
Heatsink: Passive copper heatsink
Runtime: approx. 40 minutes.
Dimensions: Length 63cm x Width 28cm x Heigth 32cm.
Weight: 8,8 kg
Material: Stainless Steel 304
Features: Focusable, the beam angle (and thus intensity ) can be adjusted, tripod-mount, bezel-stand, lanyard.
Collimator lens: Aspheric, diameter 75mm, aperture 50mm, back focal length 40mm, f-number 0.55 (Thorlabs ACl 7560 ),viewangle 84 degrees.
Main lens: Plano-convex, diameter. 262mm, aperture 250mm, back focal length 500mm, f-number 1.9 (Estimated ), (found magnifying glass ) viewangle 38 degrees.
Distance between both lenses: 440mm (plain surface to plain surface)
Distance between Led and first lens: 8 -10 -15-21mm (top of dome to plain surface lens ) :
08mm Needle:
Beam angle 0.5 degree, spotsize at 50 meter 0.4x0.4m
1.8000.000 candela, means 1 lux at 1.342 metres distance, 20 lux at 300 metres distance.
10mm Fine spot:
Beam angle 0.7 degree, 1.600.000 candela, spotsize at 50 meter Dia.0.6m
1.600.000 candela, means 1 lux at 1.265 lux at metres distance, 20 lux at 283 metres distance.
15mm Spot with hotspot:
Beam angle 2.8 degree, 375.000 candela, spotsize at 50 meter Dia. 2.3m
375.000 candela, means 1 lux at 612 metres distance, 20 lux at 137 metres distance.
25mm Flood:
Beam angle 4,7 degree, 50.000candela, spotsize at 50 meter Dia. 4.13m
50.000 candela, means 1 lux at 224 metres distance, 20 lux at 50 metres distance.
(To get consistent Lux measurements a distance of at least 25 meter was needed.)
Introduction:
Reading inspiring threads at CPF, I thought, why couldnt I do what they can...? Naturally I bought some stuff that didn't work, call it Research and Development, but I learned a lot and it was a great pass time.
I read about materials for heatsinking and heatpipes, white led tests, aspherics, data-sheets, focal lenghts, f-numbers, telescopes and beam expanders, drivers and batterys. In my search I found more explicite help from several members that answered some questions, and I thank them for their helpfulness. I like to share my findings, as the best members of CPF do. As soon as I understood how Led's work with aspherics, I had the concept thought over, it took me some longer to have the details right. It was good hobby-time, and am satisfied with the result. For me the fun is not only in the result, but in finding my way to solutions.
This might be the World's most powerful single Led-light at this moment, but only because I don't know of any equivalent beast.
How it works:
The first lens, close to the Led, captures most of the light sent out by the Led. Due to its short focal length, it captures a very reasonable part of the emitted lumen.
This light is dan forwarded, and narrowed down, to enlight the full diameter of the big lens.
This big lens magnifies the brightness of the Led for every square mm2 of its surface, which is accountable for the throw.
Due to its long focal length the outgoing beam has a somewhat narrow angle.
This double lens set-up uses the principle of a beam expander as used in Laserlight technology and eyepieces.
A single lens would be more efficient for throw, but worse in lumen, in practice I find this the best of both and most cost efficient in case you have a large lens at hand and want to utilize it. The beamangle is a result of the two lenses, in combination with the size of the led's light-emitting surface.
I used the 5 dollar Cree XRE R2, for two characteristics:
Because the light-emitting surface, the 'die', is small, the die has the highest relative surface-brightness (intensity) of commonly available and known Led's.
It projects its light in a smaller, more condensed cone than other led's, sending more Lumen in the first lens.
Naturally, in time I will ugrade this Led once there is a Led that's even more sweet.
The Led-base is sanded down to 0.1mm to minimize thermal-path to the heatsink, -thanx to Ra- pressed to the heatsink with thermal paste.
The well ventilated heatsink, copper for best properties, open structure for best airflow, a bit over-dimensioned to be on the safe side.
It still gets warm so I should ad a fan to it.
I used AA-batteries as I wanted it to be powered by batterys people are familiar with. I could have done with a single and smaller battery of other chemistry.
Direct drive give's higer Lux-readings, but readings would fall rapidly after a few minutes as the voltage of the batteries get lower. That's why I choose to use a driver, so the light output is constant for a longer time.
More technical info:
For lumen, lux, candela see Wiki.
Optics theory - fundamentals on reflectors/optics
Formula for calculating throw using aspheric lens
Main inspirations:
SST-50 homemade spotlight - EasyB's plain, simple, effective using a fresnel lens
Fat Needle 400 - long throw, thin beam - Dr.Jones's testbench
Data Bank 70 - Data's techno multi led thrower
Maxablaster - Ra's engineered thrower
HID-Killer: Adaptor for 1xCree light - Long John's first to use pre-collimator
How to make a Cree Throw - Newbie's mother of aspheric flashlights
Huygens Wiki - This light is named after Huygens, a Dutch scientist from the 16th century, kown for-among others- his telescopes. He enhanced the principle of using two converging lenses in row to reach collimating, a simple assembly for getting a short focal-length and a narrow beam. Quite useful for our use with Led's and aspheric condensor lenses. Huygens build tubeless telescopes up to 62 metres length, to be the first to tell you Saturn has a ring around it. The same principle is still used in telescopes and microscopes and binoculairs.
The tubeless design, and his urge to improve, with hands-on experiments, appealed to me, hence the name for this steampunk-tech-style.
Last edited:
