A heat sink of finned structure cools the device and dissipates waste heat by a passive way in heat transfer methods. It has been widely used in the electronic cooling industry for many years. Simple structure, safe and low-cost are the important reasons that make heat sink still popular nowadays. Besides, it still can provide a good efficiency with a proper design. Thus, these make heat sink a good choice in the passive cooling industry. However, the applied power rate of many electronics devices are getting higher as higher recently. Especially, solid state lighting with high power rate is starting to replace the traditional lighting. But due to a poor energy conversion efficiency, it may consume a large amount of power and dissipate more waste heat at the same time. In result, an un-improved heat sink won't able to handle such a large amount of waste heat and so it can't meet requirement of cooling high power rated devices. Therefore, searching for an improved heat sink which can provide a higher amount of potential in handling waste heat dissipation is the key point of study. Studying by using the computational simulation method of commercial computational fluid dynamics software Fluent is able to help us analyzing and comparing the thermal performances of improved heat sinks which have many different designs. In order to ensure the correctness of the simulation results, verifications would be done at the same time by comparing the computational conditions to the similar experimental results from foreign studies. The overall thermal resistance of heat sink and average temperature at the surface of heat source under three different inclined orientations(vertical upward, downward and horizontal) were chosen for the purpose of judging the thermal performance of heat sink. Meanwhile, parametric studies were carried out to find out the effects of fins number, fin height, fin length and fin thickness on the thermal performance of heat sink. According to the studied results, it was found that an improved heat sink which operated at twelve watts and above, it could decreased at least five degree Celsius of heat source surface temperature when it was put in either vertically upward or downward position as comparing to the un-improved heat sink. Moreover, improved heat sink in horizontal position could yield a better performance that the others which the temperature difference could reach at least twenty-five degree Celsius and above. Through the study in the parameters, we found that the distance between fins was the key point which affected the overall thermal performance of a improved heat sink. This distance was decided by the numbers of fins, fin length and also fin thickness. While the fin height had an inversely proportional relationship with the thermal resistance and heat source surface temperature. But this phenomenon would become more non-obvious as the fin height was higher than a certain level. Also, the increased mass of heat sink due to fin height might not provide a corresponding acceptable thermal performance at the same time. This implied that there was a consideration to make between choosing either the thermal performance or the heat sink mass at same time.