Ip code info
Definition of IP Codes (Ingress Protection) In the IEC (International Electrotechnical Commission) 60529 Standards document, it specifies an international classification system for the sealing effectiveness of enclosures of electrical equipment against the intrusion into the equipment of foreign bodies (i.e., tools, dust, fingers) and moisture. This classification system utilizes the letters “IP” (“Ingress Protection”) followed by two digits. (An “X” is used for one of the digits if there is only one class of protection; i.e., IP X4 which addresses moisture resistance only.)
1. Degrees of Protection – First Digit
The first digit of the IP code indicates the degree that persons are protected against contact with moving parts (other than smooth rotating shafts, etc.) and the degree that equipment is protected against solid foreign bodies intruding into an enclosure.
- – No special protection
- – Protection from a large part of the body such as a hand (but no protection from deliberate access); from solid objects greater than 50mm in diameter
- – Protection against fingers or other objects not greater than 80mm in length and 12mm in diameter
- – Protection from entry by tools, wires, etc., with a diameter or thickness greater than 2.5mm
- – Protection from entry by solid objects with a diameter or thickness greater than 1.0mm
- – Protection from the amount of dust that would interfere with the operation of the equipment 6
2. Degrees of Protection – Second Digit
Second digit indicates the degree of protection of the equipment inside the enclosure against the harmful entry of various forms of moisture (e.g. dripping, spraying, submersion, etc.).
- – No special protection
- – Protection from dripping water
- – Protection from vertically dripping water
- – Protection from sprayed water
- – Protection from splashed water
- – Protected against low-pressure jets from all directions – limited ingress permitted
- – Protected against direct sprays from all directions – limited ingress permitted
- – Protection against effects of immersion from 15cm to 1m
- – Protection against complete, continuous submersion in water from 15 meters or 50 feet
IP Code Symbols The chart below illustrates the use of special symbols in the IP classification system. In the “1st digit” columns, note the grid-like symbols next to numbers 5 and 6. In the “2nd digit” columns numbers 3-8 are symbolized by teardrop shaped symbols, sometimes enclosed in a box or a triangle, sometimes unenclosed (7-8).
WHAT IS A LUMEN?
The lumen (lm) is the SI unit for measuring the total amount of visible light emitted from a source.
WHAT IS LUX?
Lux is the SI unit for illuminance – intensity of light on a surface.
WHAT DOES COLOUR TEMPERATURE MEAN?
Colour temperature of light is quoted in degrees Kelvin. The colour temperature of light correlates to the colour of light emitted from a black-body radiator when heated to a specific temperature. This could be thought of as coal on a fire; it can be seen glowing red hot and white hot. Red hues are towards the lower/cooler end and blue hues are towards the higher/hotter colour temperatures – therefore white hot coals are a higher colour temperature than red hot coals. The colour temperature of a typical domestic incandescent light bulb is 2,700 Kelvin – an orange/red hue of white. The colour temperature of daylight is around 6,000K. White LEDs can generally be sourced from 2,200K to 10,000K.
WHAT DOES CRI MEAN?
CRI (Colour Rendition Index) is a measure of the ability of a light source to reveal the colours of various objects faithfully in comparison with an ideal or natural light source such as the sun/natural daylight. The highest possible CRI is 100. Incandescent light bulbs have CRIs of 100, fluorescent tubes range from 50 to 90 if using tri-phosphor tubes and LEDs generally range from 70 to 90CRI.
WHAT IS EFFICACY?
Efficacy is a measure of the ratio of visible light to the power consumed and is measured in lumens per Watt (lm/W).
ARE ALL LEDS THE SAME?
No – LEDs are primarily two different layers of material that conduct electricity in one direction and in doing so release photons (light). These layers vary depending on LED colour and manufacturer. These layers are assembled differently; assembled in different packages and on different bases such as plastic and ceramic, depending on the manufacturer, patents, power etc. They can include primary optics built into the package. All non RGB LEDs on the market are actually royal blue LEDs with an added phosphor to convert to a shade of white. Phosphor qualities vary significantly; the worst resulting in an inability to maintain colour over time, achieve colour repetition, and maintain light output. Most importantly, they all have varying properties when it comes to dissipating the heat generated internally; this is the main contributor to the life of the device.
WHAT VOLTAGE ARE LEDS?
LEDs are all very low voltage typically ranging from 2V to 4V depending colour and specific device.
WHAT IS THE EXPECTED LIFE OF AN LED?
Life can vary enormously depending on the quality of the device and its environmental conditions – primarily temperature and pollutants. The very long life expectancy of LEDs means that it is often not feasible to carry out real life testing in terms of time, therefore manufacturers will tend to perform relatively short term tests and then extrapolate the data to provide L70 or L80 figures. These figures are the expected light degradation curves to 70% or 80% of the initial light output over time. These curves are based on specific drive currents and temperatures and not all tests are carried out under the same conditions.
DO LEDS GET HOT?
Yes – this is also the primary factor in maximising the life of an LED. All LEDs create heat; the more powerful the device, the more heat it will create. It is imperative that the heat can leave the device and be dissipated accordingly. The core temperature of an LED in many cases could be circa 100°C.
HOW EFFICIENT ARE LEDS?
The cool white LEDs that Labcraft use are around 35% efficient in ‘real life’ operating conditions. These LEDs are one of the most efficient available. A typical automotive filament light bulb is around 2% efficient meaning 98% of the electrical power used is turned into heat. The efficacy of the same Labcraft LED would be 140 lumens per Watt compared to 10 lumens per Watt with automotive bulb.