Why do LED Lights Fail?
>>> See More Troubleshooting Guide - LED Light Strip Remote Not at https://www.deviantart.com/ledlightsblls/journal/Troubleshooting-Guide-LED-Light-Strip-Remote-Not-978202763
There are a number of basic reasons for LED lights to fail but the primary issue is heat.
Over-heating can be a result of a number of design and assembly issues but is still the cause of the majority of LED lamp failures - both in the fitting themselves and also the drivers.
LED Fittings
Everyone knows that LED’s need a heatsink which is generally incorporated into the basic design of the product.
Going back 10-15 years this resulted in heavy, large and cumbersome products which seemed to be designed for military use compared with their light and flimsy metal halide cousins.
As the technologies have improved the housings have reduced, become more streamlined and architectural. However the fundamental issue has not disappeared - LED’s create a lot of heat and need to get rid of it.
LED’s
Not all LED’s are created equal.
In the past decade a handful of manufacturers have set themselves apart from the rest by consistently delivering high performance, tried and tested LED’s that have proved to last, based on LM80 and similar tests.
Many copycat chip designs have sprung up but this is not a step worth taking a short cut on. If the LED is unreliable, almost nothing else matters - stick with one of the brand leaders.
PCB’s and Contact with the Housing
Unlike a halogen, which throws its heat forward, LED’s push their heat out the back, through the PC Board and then into the heat sink.
This conductive path is very necessary to making the system work together and provides the first potential hotspot.
The thickness and material of the PCB is part of (or should be part of!) an engineered design that considers heat dissipation from the get-go. The LED’s are generating heat, the PCB is transporting the heat into the body (or heatsink) to be taken away. If the PCB is not thick enough and doesn’t have enough heatsinking in its own right, hot spots can occur.
Consequently, many manufacturers economise here as the short-cuts are not clearly visible.
Unfortunately, they are visible when the lamp stops working for no apparent reason.
>>> See More 7 Effective Solutions for Resolving the Yeelight Only Red Light Problem at https://glose.com/activity/64fed158729416db88366c25
Housing Design
The next aspect in the thermal design is the housing.
Not only must there be enough aluminium to dissipate the heat, but it must be of a high quality and cast in a way that supports heat dissipation.
There are a number of methods of molding the aluminium and each has cost vs efficiency differences. Extrusion is common and is economical to produce, both for tooling and components, and due to the high molding pressure, is very efficient. However, because it is a linear extrusion the shape is 2 dimensional, greatly restricting the design options.
Cold forging is another option for efficiency, but often not used due to limitations on design and higher tooling costs.
Drivers
Many basic LED light fixture designs incorporate the LED driver into the design for convenience.
However, the drivers themselves generate heat and are also adversely affected by heat. Bolting them to a hot heatsink is about the worst treatment they can get and subsequently this causes premature failures. The reason for this is that one of the components used on the PCB of the driver has a gel solution to make it function. If this gel dries out, the driver fails.
The answer to this issue is to keep the drivers cool, which requires either insulation or sufficient airflow during operation.
Solution
With temperature being the biggest issue, the obvious solution is to control the temperature.
Many manufacturers choose to make their module underperform to prevent a heat build-up. This can work but also make the modules bigger and heavier than they need to be.
Our recommendation, if you are operating your lights for long periods of time or in a harsh environment, is to make sure the lights you are buying have some form of electronic temperature control.
These devices vary in type, but the result should be that they effectively control the temperature of the module to less than 90 C.
One of the most effective is a physical NTC (thermistor) which sensors the actual temperature and dims the lamp in order to maintain the temperature.
>>> See More The complete LED strip fails to illuminate at https://twitback.com/post/379976
>>> See More Troubleshooting Guide - LED Light Strip Remote Not at https://www.deviantart.com/ledlightsblls/journal/Troubleshooting-Guide-LED-Light-Strip-Remote-Not-978202763
There are a number of basic reasons for LED lights to fail but the primary issue is heat.
Over-heating can be a result of a number of design and assembly issues but is still the cause of the majority of LED lamp failures - both in the fitting themselves and also the drivers.
LED Fittings
Everyone knows that LED’s need a heatsink which is generally incorporated into the basic design of the product.
Going back 10-15 years this resulted in heavy, large and cumbersome products which seemed to be designed for military use compared with their light and flimsy metal halide cousins.
As the technologies have improved the housings have reduced, become more streamlined and architectural. However the fundamental issue has not disappeared - LED’s create a lot of heat and need to get rid of it.
LED’s
Not all LED’s are created equal.
In the past decade a handful of manufacturers have set themselves apart from the rest by consistently delivering high performance, tried and tested LED’s that have proved to last, based on LM80 and similar tests.
Many copycat chip designs have sprung up but this is not a step worth taking a short cut on. If the LED is unreliable, almost nothing else matters - stick with one of the brand leaders.
PCB’s and Contact with the Housing
Unlike a halogen, which throws its heat forward, LED’s push their heat out the back, through the PC Board and then into the heat sink.
This conductive path is very necessary to making the system work together and provides the first potential hotspot.
The thickness and material of the PCB is part of (or should be part of!) an engineered design that considers heat dissipation from the get-go. The LED’s are generating heat, the PCB is transporting the heat into the body (or heatsink) to be taken away. If the PCB is not thick enough and doesn’t have enough heatsinking in its own right, hot spots can occur.
Consequently, many manufacturers economise here as the short-cuts are not clearly visible.
Unfortunately, they are visible when the lamp stops working for no apparent reason.
>>> See More 7 Effective Solutions for Resolving the Yeelight Only Red Light Problem at https://glose.com/activity/64fed158729416db88366c25
Housing Design
The next aspect in the thermal design is the housing.
Not only must there be enough aluminium to dissipate the heat, but it must be of a high quality and cast in a way that supports heat dissipation.
There are a number of methods of molding the aluminium and each has cost vs efficiency differences. Extrusion is common and is economical to produce, both for tooling and components, and due to the high molding pressure, is very efficient. However, because it is a linear extrusion the shape is 2 dimensional, greatly restricting the design options.
Cold forging is another option for efficiency, but often not used due to limitations on design and higher tooling costs.
Drivers
Many basic LED light fixture designs incorporate the LED driver into the design for convenience.
However, the drivers themselves generate heat and are also adversely affected by heat. Bolting them to a hot heatsink is about the worst treatment they can get and subsequently this causes premature failures. The reason for this is that one of the components used on the PCB of the driver has a gel solution to make it function. If this gel dries out, the driver fails.
The answer to this issue is to keep the drivers cool, which requires either insulation or sufficient airflow during operation.
Solution
With temperature being the biggest issue, the obvious solution is to control the temperature.
Many manufacturers choose to make their module underperform to prevent a heat build-up. This can work but also make the modules bigger and heavier than they need to be.
Our recommendation, if you are operating your lights for long periods of time or in a harsh environment, is to make sure the lights you are buying have some form of electronic temperature control.
These devices vary in type, but the result should be that they effectively control the temperature of the module to less than 90 C.
One of the most effective is a physical NTC (thermistor) which sensors the actual temperature and dims the lamp in order to maintain the temperature.
>>> See More The complete LED strip fails to illuminate at https://twitback.com/post/379976
Why do LED Lights Fail?
>>> See More Troubleshooting Guide - LED Light Strip Remote Not at https://www.deviantart.com/ledlightsblls/journal/Troubleshooting-Guide-LED-Light-Strip-Remote-Not-978202763
There are a number of basic reasons for LED lights to fail but the primary issue is heat.
Over-heating can be a result of a number of design and assembly issues but is still the cause of the majority of LED lamp failures - both in the fitting themselves and also the drivers.
LED Fittings
Everyone knows that LED’s need a heatsink which is generally incorporated into the basic design of the product.
Going back 10-15 years this resulted in heavy, large and cumbersome products which seemed to be designed for military use compared with their light and flimsy metal halide cousins.
As the technologies have improved the housings have reduced, become more streamlined and architectural. However the fundamental issue has not disappeared - LED’s create a lot of heat and need to get rid of it.
LED’s
Not all LED’s are created equal.
In the past decade a handful of manufacturers have set themselves apart from the rest by consistently delivering high performance, tried and tested LED’s that have proved to last, based on LM80 and similar tests.
Many copycat chip designs have sprung up but this is not a step worth taking a short cut on. If the LED is unreliable, almost nothing else matters - stick with one of the brand leaders.
PCB’s and Contact with the Housing
Unlike a halogen, which throws its heat forward, LED’s push their heat out the back, through the PC Board and then into the heat sink.
This conductive path is very necessary to making the system work together and provides the first potential hotspot.
The thickness and material of the PCB is part of (or should be part of!) an engineered design that considers heat dissipation from the get-go. The LED’s are generating heat, the PCB is transporting the heat into the body (or heatsink) to be taken away. If the PCB is not thick enough and doesn’t have enough heatsinking in its own right, hot spots can occur.
Consequently, many manufacturers economise here as the short-cuts are not clearly visible.
Unfortunately, they are visible when the lamp stops working for no apparent reason.
>>> See More 7 Effective Solutions for Resolving the Yeelight Only Red Light Problem at https://glose.com/activity/64fed158729416db88366c25
Housing Design
The next aspect in the thermal design is the housing.
Not only must there be enough aluminium to dissipate the heat, but it must be of a high quality and cast in a way that supports heat dissipation.
There are a number of methods of molding the aluminium and each has cost vs efficiency differences. Extrusion is common and is economical to produce, both for tooling and components, and due to the high molding pressure, is very efficient. However, because it is a linear extrusion the shape is 2 dimensional, greatly restricting the design options.
Cold forging is another option for efficiency, but often not used due to limitations on design and higher tooling costs.
Drivers
Many basic LED light fixture designs incorporate the LED driver into the design for convenience.
However, the drivers themselves generate heat and are also adversely affected by heat. Bolting them to a hot heatsink is about the worst treatment they can get and subsequently this causes premature failures. The reason for this is that one of the components used on the PCB of the driver has a gel solution to make it function. If this gel dries out, the driver fails.
The answer to this issue is to keep the drivers cool, which requires either insulation or sufficient airflow during operation.
Solution
With temperature being the biggest issue, the obvious solution is to control the temperature.
Many manufacturers choose to make their module underperform to prevent a heat build-up. This can work but also make the modules bigger and heavier than they need to be.
Our recommendation, if you are operating your lights for long periods of time or in a harsh environment, is to make sure the lights you are buying have some form of electronic temperature control.
These devices vary in type, but the result should be that they effectively control the temperature of the module to less than 90 C.
One of the most effective is a physical NTC (thermistor) which sensors the actual temperature and dims the lamp in order to maintain the temperature.
>>> See More The complete LED strip fails to illuminate at https://twitback.com/post/379976
0 Comments
0 Shares