Allicdata Part #: | 904-27-2-33-2-B-0-ND |
Manufacturer Part#: |
904-27-2-33-2-B-0 |
Price: | $ 3.28 |
Product Category: | Fans, Thermal Management |
Manufacturer: | Wakefield-Vette |
Short Description: | HEAT SINK PIN FIN 27X27MM CLIP |
More Detail: | Heat Sink |
DataSheet: | 904-27-2-33-2-B-0 Datasheet/PDF |
Quantity: | 1000 |
180 +: | $ 2.97787 |
Series: | * |
Part Status: | Active |
Due to market price fluctuations, if you need to purchase or consult the price. You can contact us or emial to us: sales@allicdata.com
The term 904-27-2-33-2-B-0 may not be immediately recognizable to the layperson, but this selection of five different digits and two letters actually refers to thermal - heat sinks, a special form of technology used to advanced thermal management. Thermal - heat sinks operate by manipulating the natural circulation of air to draw heat away from a component. This is done by taking advantage of the difference in temperature between air and the heat source.
Thermal - heat sinks are designed to use a combination of convection and radiation to dissipate heat away from any given component. Convection works by moving the hot air away from the component with the use of a fan. Radiation occurs when the hot air dissipates into the surrounding environment through the heat sink itself. The process helps reduce the temperature of the component by taking the heat away from it and dissipating it into the surrounding air. Thermal - heat sinks are usually constructed out of aluminum or copper, and the fibers of the material act as fins that provide additional cooling power.
The primary application for thermal - heat sinks are in electronics, as the technology is extremely effective in managing the temperature of electronic components. Overheating can cause irreparable damage to electronic devices, and thermal - heat sinks play a vital role in keeping the temperatures of the components within a safe range. The sinks are also used in larger applications, as in the cooling of industrial metalworking equipment.
Outside of their main application in electronics, thermal - heat sinks are also used in a number of other areas. This includes cooling systems for engines, HVAC systems, and even medical treatments. In the medical field, radiators are used to help patients warm up or cool down rapidly to treat hypothermia, hyperthermia, and even respiratory infections. Heat sinks are also used in cryogenics to help the cooling of extremely cold objects and substances.
The 904-27-2-33-2-B-0 thermal - heat sinks are a hybrid design that uses both radiation and convection to cool components. This means that the primary design focuses on getting the heat away from the component, but also relies on the natural environment to help dissipate the heat. The dual design provides improved efficiency when compared to other sinks, as the extra cooling power of the fins and fan allows the heat to be drawn away faster.
The 904-27-2-33-2-B-0 thermal - heat sinks are designed for use in cases where the components to be cooled are in close proximity. In these scenarios, the fan helps to disperse the heat away from the component faster. In cases where the components are spaced further apart, the design can still be employed, but the fan may not prove to be as effective.
In order to maximize the efficiency of a 904-27-2-33-2-B-0 thermal - heat sink, it is important to make sure that the fan is placed in the optimal position. The fan should be able to reach the hottest parts of the component, as this will ensure that the dissipated heat is quickly taken away from the component. Additionally, the fins of the sink should be kept free of dust and debris, as this can reduce the sink’s efficiency.
The 904-27-2-33-2-B-0 thermal - heat sinks are a reliable and efficient way to reduce temperatures in electronic components. By using a combination of convection and radiation, these sinks can quickly dissipate heat away from components, allowing them to run at optimal temperatures without risk of overheating or damage. In order to maximize its effectiveness, the fan should be placed in the most efficient position, and the fins should be kept clean from any debris.
The specific data is subject to PDF, and the above content is for reference