Do we really understand heat? To understand insulation and how unique products like Super Therm® work, we must understand the basics, like: heat follows cold and more. Read this tutorial to increase your knowledge. This tutorial is simply intended to give some of the basics of heat energy, and how it relates to insulation and ceramic coatings. It is not intended to be comprehensive.
There are three basic types of heat transfer: conduction, convection, and radiation.
Conduction:
- Energy transfer through solid objects
- Different types of solids transmit heat differently than others, with metals being among the best for heat transfer, and ceramics being some of the most resistant.
- Example: heat from a cast iron frying pan moves through the handle to your hand.
Convection:
- Energy transfer through the movement of gases or liquids.
- Most of heat energy transferred in this manner occurs when heated gases start moving, forming currents that carry the energy from one location to another.
- Example: forced air heating uses convection to heat a room.
Radiation:
- Energy transferred through electromagnetic waves.
- Air absorbs very little energy from radiation. When radiative energy strikes a solid surface, it heats the surface, and the energy is converted to conduction.
- Example: energy from the sun is in the form of radiation, which is the largest source of heat gain in a building.
Super Therm® works against all three forms of heat transfer. It is most effective against radiation, as it reflects over 95% of the energy from the sun.
Super Therm® fights convection because it allows no air movement through the coating, while avoiding taking up any heat from the air itself.
Only Super Therm® resists heat transfer through conduction as well, due to the unique ceramics used to resist the movement of heat through the coating itself.
Also note that energy is constantly being converted from one heat transfer method to another. Using an uninsulated roof can demonstrate this quite nicely:
- Energy comes down from the sun in the form of radiation.
- A small amount of heat is absorbed by the air, transforming it into convective heat.
- When the radiation from the sun and the convective heat from the air come in contact with a roof, they heat the surface converting this energy into conductive heat transfer, which heats the metal. Super Therm® coated on a roof prevents this from happening, by reflecting the suns energy before it reaches the metal underneath.
- As the metal gains heat, it heats the air inside the building, forming air convection currents. When Super Therm® is used, the metal doesn't have a chance to heat up, and thus the building remains cool
- In this way, Super Therm® heat builds up underneath the roof, and eventually the entire building.
A simple rule for the direction of transfer of heat is this: Heat follows cold..
- Heat always follows the path of least resistance: whichever direction is cooler is the direction the heat will move.
- What this means is that if there are two objects with different temperatures, the hotter object will always transfer heat to the colder object.
- For example, when the temperature on one side of a roof is hotter than the other, heat is transferred, through conduction, from the hot side to the cool side through the roof until the temperatures are equal.
- The belief that heat rises is only true in one circumstance: heated air will rise as it forms convection currents. Heat energy itself normally moves in the path with the least energy (the coldest surface), whether it be up, down, or sideways.
The R-value is simply a measure of how well a conventional insulation resists heat transfer through conduction only. The greater the value, the greater the ability of the insulation to resist and absorb conductive heat.
A little bit of history: The R-value system was originally developed when the first mass insulation, fibreglass, was first developed, to give a rating for it's ability to resist and absorb heat.
- When the tests were put into place, they were designed to measure the properties of fibreglass, and to ensure that the highest results would be obtained.
- The tests were all done under very specific and controlled conditions with regard to the difference in temperature, humidity of the material, and an absence of air movement.
- Normal insulations, including fibre-based (fibreglass, cellulose, etc.) or solid insulation (polyurethane foam, SM board, etc.) contains small pockets of gases, usually air.
- Heat is transferred slowly through most gases, and thus through the insulation. The pockets of air are small enough that convection currents do not develop inside of the pockets, and thus the heat moves very slowly.The smaller the air pockets, the greater the resistance to heat transfer and thus the greater the R-value. This is why different insulations have different values.
- As a side effect, insulations absorb heat as it moves from the hot side to the cold side of the material.
For example, an air conditioned building in the summer:
- The warm temperatures outside of the building are always attempting to penetrate into the cooler areas inside the building.
- Insulation in the building resists this heat transfer, slowly absorbing the heat until it is either saturated, or the temperature difference decreases.
- Once saturated, the heat passes through the insulation into the cooler area.
- In the evening, when the outside temperature decreases, the heat begins transferring from the warmer insulation, to the cooler air outside of the building.
The R-value system only accounts for the abilities of insulation against conduction. Against the other two forms of heat transfer (convection and radiation) the effectiveness varies greatly depending on the type of insulation.
For fibreglass, the results of these tests change dramatically under even slightly different conditions:
- If 1.5% humidity is introduced, fibreglass loses roughly 35% of it's R-value, due the fact that water is a much better conductor than air.
- All tests are done only at temperatures in which fibreglass would perform best. Above and below this temperature fibreglass rapidly loses effectiveness and the R-value is lower.
- Air movement also greatly affects the R-value of fibreglass, as heated air moving through the fibreglass drastically reduces it's conductive value.
R-value testing methods do not reflect real world conditions, which can vary greatly with regard to all of these factors: material humidity, temperature differences, and air movement.
R-hodnotenie u pevnej (napr. penovej) izolácie je oveľa spoľahlivejšie ako u vatovej či vlnovej, pretože na pevnú izoláciu tak nevplýva vlhkosť a pohyby vzduchu.
Unfortunately these same tests are still used today, despite the fact that new insulations have been introduced into the market. Solid insulations are even more effective than their R-value would suggest, as they are completely unaffected by humidity, temperature, and air movement, as well as having long-term thermal resistance. Super Therm®'s performance is not affected by moisture or air movement
Another downfall is radiation is not accounted for in R-value testing. If stopping radiation was included in R-value testing, Super Therm® would outperform all other insulation.
Super Therm® works against all three forms of heat transfer. It is most effective against radiation, as it reflects over 95% of the energy from the sun.
Super Therm® fights convection because it allows no air movement through the coating, while avoiding taking up any heat from the air itself.
Only Super Therm® resists heat transfer through conduction as well, due to the unique ceramics used to resist the movement of heat through the coating itself.
This simply means that heat never builds up. Normal insulations resist and store heat, thus preventing it from passing through the bulk.
Super Therm® stops heat movement so effectively that heat hardly builds up at all. It strongly resists any energy movement through radiation, conduction and convection, through its unique blend of ceramics.
Lower energy costs, as air conditioners need to work less to dispel heat that never has a chance to collect.
Less heat stress on personnel and livestock, equals increased productivity.A longer lifespan for the surface it is coated on, as the metal itself is protected from expansion and contraction due to the rapid heating and cooling cycles during the days.
The coatings themselves protect against weathering and damage from the environment. Super Therm® will provide 20 years of protection.
Basically, the energy costs must be examined>
If heating costs in the winter are considerably less than the cooling costs in the summer, Super Therm® is the choice. This is especially true where heating is not an issue: in coolers, freezers, and arenas where the sole objective is to maintain a low temperature.
Izolácia proti mrazu:
Ak potrebujete odizolovať objekt voči mrazu a chladu tu pomôže bežná izolácia. Avšak použitie pevnej penovej izolácie bude určite lepšia voľba ako použitie sklo-vatového či iného vlhko sajúceho materiálu. Pozor treba však tiež dávať pozor aby penová izolácia nezadusila Váš dom, ale aby bola paropriepustná, lebo inak budete mať doma síce teplo ale i vlhko a plesne.
Najdokonalejšou vysoko-paropriepustnou penovou izoláciou na trhu je STYREXON (www.styrexon.sk).
Izoláciu STYREXON používame i v našich kombinovaných systémoch pre oblasti s chladnejším podnebím. Bližšie v časti KOMBINOVANÉ SYSTÉMY.
Radiación - Proceso por el cual el calor es irradiado por los cuerpos en los espacios abiertos mediante rayos, por ejemplo, radiaciones solares.
Temperatura - El grado de temperatura es medido en grados Celsius (°C), las diferencias de temperatura son medidas en grados Kelvin (K).
Paso del aire - Entrada de corrientes de aire en el edificio a través de grietas o la estructura de los materiales.
Condensación - Condensación es la transformación de un vapor de su estado gaseoso al estado líquido por efecto del contacto con una superficie fría.
Conducción - Paso del calor a través o a lo largo de un material hasta otro material con el que está en contacto.
Flujo - Transmisión de calor con el movimiento de aire.
Absorción - capacidad de absorber la radiación solar recibida.
Emisividad - Puede definirse de dos maneras:
- Emisividad de absorción: (capacidad de retener las radiaciones caloríficas), se define como la medida de radiación, liberada por la superficie. Los materiales con superficies oscuras tienen una alta emisividad acercándose al límite máximo superior de 1,0 reteniendo y conservando un alto volumen de la radiación. Por el contrario, los cuerpos con superficies reflectantes como espejos o aluminio pulido, tienen una baja emisividad de valor 0,08 , es decir, no retienen prácticamente ninguna radiación en sí mismos. Super Therm® tiene el más bajo valor absoluto de emisividad 0.05.
- Emisividad Infrarroja: (capacidad para desprenderse de calor – irradiarlo), también se define como la medida de radiación, liberada por la superficie. Super Therm® tiene una Emisividad de radiación Infrarroja muy alta (más del 95% / valor 0,95), lo que significa que es extremadamente eficaz para liberar incluso el reducido volumen de calor que haya absorbido.
Pérdida de calor - Paso del calor de un espacio interior a un espacio exterior a través de la conducción, flujo o radiación.
Conducción de calor - Proporción en la que el calor pasa por los materiales, se mide en vatios por metro cuadrado de superficie que tiene que atravesar a la temperatura de 1 grado Kelvin por metro atravesado, de forma abreviada W/m.K.
Peso calorífico - Es el peso de la construcción que se utiliza para absorber calor solar a lo largo del día y que posteriormente se libera durante la noche.
Resistencia media al calor - El factor R- de temperatura es la unidad física de medida que representa las propiedades de aislamiento térmico de la construcción. El objetivo a conseguir es obtener el mayor valor del factor R. La Resistencia al Calor R expresa la resistencia por 1 m2 de construcción al paso de energía calorífica que suponga una diferencia de temperatura de 1 K.
Material permeable al vapor de agua - El material permeable al vapor de agua evita el paso del agua pero al mismo tiempo „respira“, es decir, deja pasar el vapor de agua.
