This application claims priority to Taiwan Application Serial Number 099140008, filed Nov. 19, 2010, which is herein incorporated by reference.
1. Field of Invention
The present invention relates to a heat dissipating device. More particularly, the present invention relates to a fan structure.
2. Description of Related Art
A computer system (e.g. personal computer, server host etc.) produces waste heat in operation. With the increase of computer system efficiency, the waste heat produced by the computer system in operation is greatly increased accordingly. If the waste heat produced in the operation of the computer system is not removed, the computer system performance would be reduced or even a computer system crash or damage may be caused. Therefore, a heat dissipating device is needed for removing the waste heat produced by the computer system in operation.
In general, the heat dissipating device in the computer system connects a heat-generating element and a heat dissipating fin disposed at an airflow outlet of the fan with a heat pipe. The heat produced by the heat-generating element is conducted to the heat dissipating fin through the heat pipe, so that the heat on the heat dissipating fin is taken away by an airflow blown by the fan. However, the heat dissipating device needs plural components in cooperation, so the cost is high. Or, there is another heat dissipating method in which a cover plate of the fan is in direct contact with the heat-generating element without additionally using the heat dissipating fin. However, the heat exchange efficiency of this heat dissipating method is insufficient.
Therefore, there is a need to reduce the number of components of the heat dissipating device without reducing the heat dissipating efficiency.
Therefore, the present invention is directed to provide a heat dissipating device, which reduces the number of required components and effectively dissipates heat.
According to an embodiment of the present invention, a heat dissipating device includes a fan body, an upper fan cover and a lower fan cover. The fan body has an airflow outlet. The upper fan cover and the lower fan cover are assembled on the fan body. The upper fan cover includes an upper cover front portion, and multiple upper cover recessions disposed at the upper cover front portion. The upper cover recessions are located in front of the airflow outlet.
Each of the upper cover recessions includes a first bottom and two first side walls located on two sides of the first bottom. The heat dissipating device may further include a heat pipe with a first end contacting a heat source and a second end contacting the first bottom. The lower fan cover may include a lower cover front portion and multiple lower cover recessions disposed at the lower cover front portion. The lower cover recessions are located in front of the airflow outlet. The second end of the heat pipe may be in contact with the lower cover recessions. The heat dissipating device may further include a heat plate. The heat plate is disposed at the first end of the heat pipe to contact the heat source. The upper fan cover may further include an extending portion. The extending portion is in contact with another heat source. A material of the upper fan cover and the lower fan cover can be copper or aluminum.
The upper cover recessions or the lower cover recessions may be directly formed on the upper fan cover or the lower fan cover by stamping, thus the material cost and the number of components can be reduced. The heat dissipating device further expands a heat exchange area by the upper cover recessions disposed in front of the airflow outlet, thereby the heat exchange efficiency of the heat dissipating device can be effectively improved.
The following objectives, features, advantages and embodiments of the present invention can be more fully understood, with reference made to the accompanying drawings as follows:
Hereinafter, the spirit of the present invention will be illustrated clearly with reference to the drawings and detailed description, and those skilled in the art can make variations and modifications under the teaching of the present invention with reference to the preferred embodiments without departing from the spirit and scope of the present invention.
Referring to
Each of the upper cover recessions 124 has a first bottom 126 and two first side walls 128 located on two sides of the first bottom 126. Each of the upper cover recessions 124 has an approximately U-shaped cross-section. The upper cover recessions 124 may be directly formed on the upper fan cover 120 by stamping. In other words, the upper cover recessions 124 are integrally formed on the upper cover front portion 122.
The upper cover recessions 124 are located in front of the airflow outlet 112. The first bottom 126 and the first side walls 128 of the upper cover recessions 124 can increase the heat exchange area with the airflow from the airflow outlet 112, thereby the heat exchange efficiency of the upper fan cover 120 can be effectively increased.
The heat dissipating device 100 may further include a heat pipe 140. The material of the heat pipe 140 may be a metal with a good thermal conductivity, such as copper or aluminum. A first end 142 of the heat pipe 140 is in contact with a heat source 150, and a second end 144 of the heat pipe 140 is in contact with the first bottom 126 of the upper cover recessions 124. In this manner, the heat produced by the heat source 150 may be transferred to the upper cover recessions 124 through the heat pipe 140, and then is dissipated after exchanging heat with the airflow blown from the airflow outlet 112.
The heat dissipating device 100 may further include a heat plate 160. The material of the heat plate 160 may be metal with good thermal conductivity, such as copper or aluminum. The heat plate 160 is disposed at the first end 142 of the heat pipe 140 and is in contact with the heat source 150. The heat plate 160 can increase the heat exchange area with the heat source 150, thereby the heat exchange efficiency of the heat pipe 140 with the heat source 150 can be improved.
Referring to
Each of the upper cover recessions 124 has the first bottom 126 and two first side walls 128 located on two sides of the first bottom 126. Each of the upper cover recessions 124 has an approximately U-shaped cross-section. The upper cover recessions 124 may be directly formed on the upper fan cover 120 by stamping. In other words, the upper cover recessions 124 are integrally formed on the upper cover front portion 122.
Each of the lower cover recessions 134 has a second bottom 136 and two second side walls 138 located on two sides of the second bottom 136. Each of the lower cover recessions 134 has an approximately U-shaped cross-section. The lower cover recessions 134 may be directly formed on the lower fan cover 130 by stamping. In other words, the lower cover recessions 134 are integrally formed on the lower cover front portion 132.
The upper cover recessions 124 and the lower cover recessions 134 are located in front of the airflow outlet 112. The first bottom 126 and the first side walls 128 of the upper cover recessions 124 and the second bottom 136 and the second side walls 138 of the lower cover recessions 134 can increase the heat exchange area with the airflow from the airflow outlet 112, thereby the heat exchange efficiency of the upper fan cover 120 and the lower fan cover 130 can be effectively increased.
The heat dissipating device 100 may further include the heat pipe 140. The material of the heat pipe 140 is a metal with a good thermal conductivity, such as copper or aluminum. The first end 142 of the heat pipe 140 is in contact with the heat source 150, and the second end 144 of the heat pipe 140 is in contact with the first bottom 126 of the upper cover recessions 124 and the second bottom 136 of the lower cover recessions 134. In this manner, the heat produced by the heat source 150 may be transferred to the upper cover recessions 124 and the lower cover recessions 134 through the heat pipe 140, and then is dissipated after exchanging heat with the airflow blown from the airflow outlet 112.
The heat dissipating device 100 may further include the heat plate 160. The material of the heat plate 160 may be a metal with a good thermal conductivity, such as copper or aluminum. The heat plate 160 is disposed at the first end 142 of the heat pipe 140 and is in contact with the heat source 150. The heat plate 160 can increase the heat exchange area with the heat source 150, thereby improving the heat exchange efficiency of the heat pipe 140 with the heat source 150.
Referring to
Each of the upper cover recessions 124 has the first bottom 126 and two first side walls 128 located on two sides of the first bottom 126. Each of the upper cover recessions 124 has an approximately U-shaped cross-section. The upper cover recessions 124 may be directly formed on the upper fan cover 120 by stamping. In other words, the upper cover recessions 124 are integrally formed on the upper cover front portion 122.
Each of the upper cover recessions 124 has the first bottom 126 and two first side walls 128 located on two sides of the first bottom 126. Each of the upper cover recessions 124 has an approximately U-shaped cross-section. The upper cover recessions 124 may be directly formed on the upper fan cover 120 by stamping. In other words, the upper cover recessions 124 are integrally formed on the upper cover front portion 122.
The upper cover recessions 124 are located in front of the airflow outlet 112. The first bottom 126 and the first side walls 128 of the upper cover recessions 124 can increase the heat exchange area with the airflow from the airflow outlet 112, thereby the heat exchange efficiency of the upper fan cover 120 can be effectively increased.
The upper fan cover 120 further includes an extending portion 170. The extending portion 170 extends outwards from the fan body 110 to the heat source 150 and is in contact with the heat source 150. The shape of the extending portion 170 may be designed according to the path from the fan body 110 to the heat source 150. The heat source 150 may exchange heat with the extending portion 170 in contact with the heat source 150, so that the heat produced by the heat source 150 is conducted through the extending portion 170 to the upper cover recessions 124, and the upper cover recessions 124 exchange heat with the airflow blown from the airflow outlet 112 to take away the heat.
Referring to
Each of the upper cover recessions 124 has the first bottom 126 and two first side walls 128 located on two sides of the first bottom 126. Each of the upper cover recessions 124 has an approximately U-shaped cross-section. The upper cover recessions 124 may be directly formed on the upper fan cover 120 by stamping. In other words, the upper cover recessions 124 are integrally formed on the upper cover front portion 122.
Each of the lower cover recessions 134 has the second bottom 136 and two second side walls 138 located on two sides of the second bottom 136. Each of the lower cover recessions 134 has an approximately U-shaped cross-section. The lower cover recessions 134 may be directly formed on the lower fan cover 130 by stamping. In other words, the lower cover recessions 134 are integrally formed on the lower cover front portion 132.
The upper cover recessions 124 and the lower cover recessions 1.34 are located in front of the airflow outlet 112. The first bottom 126 and the first side walls 128 of the upper cover recessions 124 and the second bottom 136 and the second side walls 138 of the lower cover recessions 134 can increase the heat exchange area with the airflow from the airflow outlet 112, thereby the heat exchange efficiency of the upper fan cover 120 and the lower fan cover 130 can be effectively increased.
The upper fan cover 120 further includes the extending portion 170. The extending portion 170 extends outwards from the fan body 110 to the heat source 150 and is in contact with the heat source 150. The shape of the extending portion 170 may be designed according to the path from the fan body 110 to the heat source 150. The heat source 150 may exchange heat with the extending portion 170 in contact with the heat source 150, so that the heat produced by the heat source 150 is conducted through the extending portion 170 to the upper cover recessions 124, and the upper cover recessions 124 exchange heat with the airflow blown from the airflow outlet 112 to take away the heat.
Referring to
Each of the upper cover recessions 124 has the first bottom 126 and two first side walls 128 located on two sides of the first bottom 126. Each of the upper cover recessions 124 has an approximately U-shaped cross-section. The upper cover recessions 124 may be directly formed on the upper fan cover 120 by stamping. In other words, the upper cover recessions 124 are integrally formed on the upper cover front portion 122.
Each of the lower cover recessions 134 has the second bottom 136 and two second side walls 138 located on two sides of the second bottom 136. Each of the lower cover recessions 134 has an approximately U-shaped cross-section. The lower cover recessions 134 may be directly formed on the lower fan cover 130 by stamping. In other words, the lower cover recessions 134 are integrally formed on the lower cover front portion 132.
The upper cover recessions 124 and the lower cover recessions 134 are located in front of the airflow outlet 112. The first bottom 126 and the first side walls 128 of the upper cover recessions 124 and the second bottom 136 and the second side walls 138 of the lower cover recessions 134 can increase the heat exchange area with the airflow from the airflow outlet 112, thereby the heat exchange efficiency of the upper fan cover 120 and the lower fan cover 130 can be effectively increased.
The heat dissipating device 100 may further include the heat pipe 140. The material of the heat pipe 140 is a metal with a good thermal conductivity, such as copper or aluminum. The first end 142 of the heat pipe 140 is in contact with the heat source 150, and the second end 144 of the heat pipe 140 is in contact with the first bottom 126 of the upper cover recessions 124 and the second bottom 136 of the lower cover recessions 134. In this manner, the heat produced by the heat source 150 may be transferred to the upper cover recessions 124 and the lower cover recessions 134 through the heat pipe 140, and then is dissipated after exchanging heat with the airflow blown from the airflow outlet 112.
The heat dissipating device 100 may further include the heat plate 160. The material of the heat plate 160 may be a metal with a good thermal conductivity, such as copper or aluminum. The heat plate 160 is disposed at the first end 142 of the heat pipe 140 and is in contact with the heat source 150. The heat plate 160 can increase the heat exchange area with the heat source 150, thereby the heat exchange efficiency of the heat pipe 140 with the heat source 150 can be improved.
The upper fan cover 120 may further include the extending portion 170. The extending portion 170 extends outwards from the fan body 110 to another heat source 180 and is in contact with the heat source 180. The shape of the extending portion 170 may be designed according to the path from the fan body 110 to the heat source 180. The heat source 180 may exchange heat with the extending portion 170 in contact with the heat source 180, so that the heat produced by the heat source 180 is conducted through the extending portion 170 to the upper cover recessions 124, and the upper cover recessions 124 exchange heat with the airflow blown from the airflow outlet 112 to take away the heat.
It should be known from the above preferred embodiments of the present invention that the application of the present invention has the following advantages. The upper cover recessions or the lower cover recessions may be directly formed on the upper fan cover or the lower fan cover by stamping, which saves the material cost and the number of components. The heat dissipating device further expands the heat exchange area by the upper cover recessions disposed in front of the airflow outlet, thereby effectively improving the heat exchange efficiency of the heat dissipating device.
Although the present invention has been described with reference to the above embodiments, these embodiments are not intended to limit the present invention. It will be apparent to those skilled in the art that various modifications and variations can be made without departing from the scope or spirit of the present invention. Therefore, the scope of the present invention shall be defined by the appended claims.
Number | Date | Country | Kind |
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099140008 | Nov 2010 | TW | national |