TW201422121A - Electronic device - Google Patents

Abstract

An electronic device including a mother board, a plurality of heat-generating modules disposed on the mother board along a horizontal-direction, a first electronic module disposed at a front-side of the mother board along a vertical-direction, a second electronic module laminated on the first electronic module, a fan module located at a rear-side of the mother board along the horizontal-direction and toward the heat-generating module and the second electronic module, and a wind shield is provided. The wind shield covers the heat-generating module with a partition to form a lower airflow channel and an upper airflow channel, wherein the wind shield guides a first airflow provided by the fan module to flow through the heat generating module along the lower airflow channel and guides a second airflow provided by the fan module to flow to the second electronic module along the upper airflow channel without through the heat-generating module.

Description

Electronic device

The present invention relates to an electronic device, and more particularly to a server.

In recent years, with the rapid development of technology, the operation speed of electronic devices has been continuously improved. In addition, as the performance of electronic devices increases, the heating power of electronic components of electronic devices continues to rise. In order to prevent temporary or permanent failure of electronic components from overheating, electronic devices must provide sufficient heat dissipation for electronic components. Therefore, for high-heat-power electronic components, such as central processing units or graphics wafers, heat-dissipating modules such as heat-dissipating fins are usually added to reduce the temperature of these electronic components. In addition, electronic components are typically located within the housing of the electronic device. In order to allow the heat absorbed by the heat dissipation module to be fully discharged outside the casing, the heat convection efficiency in the casing is also one of the concerns.

In the case of a server, since the server must have sufficient stability and reliability, the service interruption provided can be avoided. Therefore, a flow guiding structure for assisting heat dissipation is usually disposed in the casing of the server to increase the efficiency of heat convection. For example, the server can arrange the fan on one side of the motherboard, and set different air hoods in front of the fan and electronic parts such as power supply or hard disk, so that the airflow blown by the fan can pass through the air hood. The guiding and flowing into these electronic parts, so that the heat generated by the electronic parts escapes outside the casing, thereby lowering the temperature of the server and stabilizing its operation.

However, since the air hood can guide the flow of the airflow blown by the fan, the arrangement of the air hood affects the heat dissipation efficiency of the electronic device. That is, after the airflow passes through the hot electronic component, the airflow entrains the heat generated by the electronic component to raise the temperature. At this point, the same airflow can no longer continue to cool other electronic components. Therefore, it is easy to cause the heat dissipation efficiency of the electronic device to be poor.

The invention provides an electronic device with good heat dissipation efficiency.

The present invention provides an electronic device including a motherboard, a plurality of heat generating modules, a first electronic module, a second electronic module, a fan module, and an air guiding cover. The heating module is disposed on the motherboard along a lateral direction. The first electronic module is disposed on a front side of the motherboard along a longitudinal direction perpendicular to the lateral direction. The second electronic module is disposed on the front side of the motherboard and stacked on the first electronic module. The fan module is laterally located on a rear side of the motherboard relative to the front side and faces the heat generating module and the second electronic module. The air guiding cover covers the heating module and has a partition extending from the fan module to the first electronic module to form a lower air flow passage between the partition plate and the main board, and an upper layer is formed above the partition plate An air flow passage, wherein the air hood guides a first airflow provided by the fan module to flow through the heat generating module along the lower airflow passage, and guides a second airflow provided by the fan module along the upper airflow passage without the heat generating module Flow to the second electronic module.

In an embodiment of the invention, the electronic device further includes a power hood, wherein the first electronic module is a power module. Power module There is a power opening, and the power opening faces the fan module and faces the lower air flow channel and the heating module. The power guiding hood is disposed on the power module and shields part of the power opening to block the first airflow flowing through the heating module from flowing into the power module.

In an embodiment of the invention, the power supply air hood has an air inlet, located at one side of the power hood and corresponding to a portion of the power supply opening that is not covered by the power hood, so that the fan module A third airflow is provided to flow from a gap of the air hood to the air inlet and into the power module via the power hood.

In an embodiment of the present invention, the electronic device further includes a power cord connected to the motherboard and the power module, wherein the power hood has an inner surface facing the power opening and an outer surface facing the fan module, the power source The wire is disposed outside the power hood to avoid interference with the motherboard, and the second airflow flows from the power opening through the inner surface into the power module.

In an embodiment of the invention, the power supply air hood has a cable hook, which is located outside the power hood, and the power cable is fixed to the power hood via the cable hook.

In an embodiment of the invention, the air hood includes an air inlet and a plurality of first air outlets. The air inlet is located on a first side of the air guiding cover corresponding to the fan module, and the first air outlet is disposed on the lower air flow channel and corresponding to the heat generating module and located on a second side of the air guiding cover relative to the first side, The first airflow can be flowed through the heat generating module from the air inlet through the first air outlet.

In an embodiment of the invention, the fan module includes a fan frame and a plurality of fans. The fan is disposed in the fan frame, the fan frame has at least one positioning hole, the air inlet has at least one positioning post, and the air guiding cover passes the positioning column Correspondingly, it is inserted into the positioning hole and assembled to the fan module.

In an embodiment of the invention, each of the heat generating modules includes a heat generating component, a heat dissipating component, and a heat dissipating outer casing. The heat dissipating component is disposed in the heat dissipating housing and is thermally coupled to the heat generating component. The heat dissipating outer casing has a engaging convex portion, and each of the first air outlets has a corresponding engaging member, and the engaging member has a engaging hook portion, and the air guiding cover is correspondingly engaged to the engaging convex portion via the engaging hook portion And fixed to the heating module.

In an embodiment of the present invention, the engaging member has a pressing portion, and the pressing portion protrudes from the first air outlet, and the air guiding cover releases the engagement between the engaging hook portion and the engaging convex portion by pressing the pressing portion. relationship.

In an embodiment of the present invention, the electronic device further includes at least one memory module disposed on the motherboard in a lateral direction and adjacent to the heat generating module, wherein the air guiding cover further includes at least one second air outlet disposed on the The lower airflow channel is corresponding to the memory module and is located on the second side of the air hood and adjacent to the first air outlet, so that the first airflow can flow from the air inlet through the second air outlet through the memory module.

In one embodiment of the present invention, the number of the heat generating module and the memory module are two and are arranged in a staggered manner on the motherboard, and the number of the first air outlet and the second air outlet are respectively two. And being staggered to each other and located on the second side, so that the first air outlet and the second air outlet respectively correspond to the heat generating module and the memory module.

In an embodiment of the present invention, the electronic device further includes a hard disk air hood, wherein the second electronic module is a hard disk module, the hard disk module has a hard disk opening, and the hard disk opening faces the fan. Module. Hard disk air hood setting The hard disk module is rotatable relative to the hard disk module to shield or expose the hard disk opening. When the hard disk air hood exposes the hard disk opening, the second airflow flows into the hard disk module, and the hard disk air hood can be fixed to the power air hood to block the first airflow flowing through the heating module into the hard disk. Module.

In an embodiment of the invention, the hard disk air hood has a fixed hook, and the power air hood has a fixing hole located at a top of one of the power hoods. When the hard disk air hood exposes the hard disk opening, the hard disk air hood is fixed to the power air hood by engaging the fixing hook to the fixing hole.

In an embodiment of the invention, the electronic device further includes a chassis. The chassis has a receiving space, and the motherboard and the fan module are disposed in the chassis, so that the first airflow and the second airflow flow in the accommodating space through the air hood and flow out of the chassis for heat dissipation.

Based on the above, the present invention provides an electronic device in which an air hood covers a heat generating module and forms a lower air flow passage and an upper air flow passage through a partition to guide the flow of the first air flow provided by the fan module along the lower air flow passage. Passing through the heating module, and guiding a second airflow provided by the fan module to flow along the upper airflow channel to the second electronic module without passing through the heating module to reduce the operating temperature of the heating module and the second electronic module respectively . Accordingly, the electronic device has good heat dissipation efficiency.

The above described features and advantages of the present invention will be more apparent from the following description.

1 is a schematic diagram of an electronic device according to an embodiment of the present invention. Figure 2 is Figure 1 is a schematic diagram of the electronic device in another perspective. To make the drawings clearer, the chassis 102 is omitted from FIG. Referring to FIG. 1 and FIG. 2 , in the embodiment, the electronic device 100 includes a motherboard 110 , a first electronic module 120 , two heat generating modules 130 , two memory modules 140 , a fan module 150 , and an air guiding cover . 160. The power hood 170, the second electronic module 180, and the hard disk hood 190. The electronic device 100 is, for example, a server, but the present invention does not limit the type of the electronic device 100.

Specifically, in the embodiment, the electronic device 100 has a chassis 102, and the chassis 102 has an accommodation space S. The motherboard 110 and the fan module 150 are disposed in the chassis 102. The two heat generating modules 130 are disposed on the motherboard 110 in the lateral direction H. The first electronic module 120 is disposed on the front side F of the motherboard 110 in a longitudinal direction V perpendicular to the lateral direction H. The second electronic module 180 is disposed on the front side F of the motherboard 110 and stacked on the first electronic module 120 . The two memory modules 140 are disposed on the motherboard 110 in the lateral direction H and adjacent to the heat generating module 130.

Since the number of the heat generating module 130 and the memory module 140 are respectively two, the heat generating module 130 and the memory module 140 of the present embodiment are arranged on the motherboard 110 in a staggered manner. However, in other embodiments, the electronic device can adjust the number and position of the heat generating module 130 and the memory module 140 according to requirements, and the invention is not limited thereto.

On the other hand, the fan module 150 is disposed in the chassis 102 along the lateral direction H and is located on the rear side B of the motherboard F relative to the front side F and electrically connected to the motherboard 110. The fan module 150 faces the heat generating module 130 and memorizes The body module 140, the first electronic module 120 and the second electronic module 180 to make the fan The airflow provided by the module 150 is blown to the heat generating module 130, the memory module 140, the first electronic module 120, and the second electronic module 180.

Specifically, in the embodiment, the air hood 160 is fixed to the fan module 150 and the heat generating module 130 by being assembled. The air hood 160 covers the heat generating module 130 and has a partition 160a extending from the fan module 150 to the first electronic module 120 to form a lower airflow channel C1 between the partition 160a and the motherboard 110. An upper air flow passage C2 is formed above the partition 160a.

The air hood 160 guides the first airflow A1 provided by the fan module 150 to flow through the heat generating module 130 along the lower airflow channel C1, and guides the second airflow A2 provided by the fan module 150 along the upper airflow channel C2 without the heating module. The group 130 flows to the second electronic module 180. Therefore, the first airflow A1 and the second airflow A2 provided by the fan module 150 respectively flow to the heat generating module 130 and the memory module 140 through the layering of the lower airflow channel C1 and the upper airflow channel C2 of the air guiding hood 160. The first electronic module 120 and the second electronic module 180 are used to improve the heat dissipation efficiency of the electronic device 100.

In addition, in the embodiment, the first electronic module 120 is a power module 120a, and the power hood 170 is disposed on the power module 120a. After the first airflow A1 flows along the lower airflow channel C1 through the heat generating module 130 and the memory module 140 and heats up and heats up, if the heated first airflow A1 flows into the power module 120a, the power mode will be affected. The heat dissipation performance of group 120a. Therefore, by providing the power hood 170, the first airflow A1 flowing through the heat generating module 130 and the memory module 140 can be effectively blocked from flowing into the power module 120a. However, the present invention does not limit the type of the first electronic module 120, and only The power module 120a will be described as the first electronic module 120.

It can be seen that the first airflow A1 and the second airflow A2 provided by the fan module 150 can flow in the accommodating space S of the chassis 102 through the guiding of the air hood 160, and carry the electronic components of the electronic device 100. The heat dissipated during the operation is dissipated to the outside of the electronic device 100, thereby reducing the operating temperatures of the first electronic module 120, the heat generating module 130, the memory module 140, and the second electronic module 180. In addition, the power hood 170 can effectively block the first airflow A1 that flows through the heating module 130 to prevent the first airflow A1 from flowing into the power module 120a and affecting the heat dissipation performance. The air hood 160 and the power hood 170 are described in sequence below.

3 is a schematic view of the air hood of FIG. 1. Referring to FIG. 1 and FIG. 3 simultaneously, in the embodiment, the air hood 160 includes an air inlet 162, two first air outlets 164, and two second air outlets 166. The air inlet 162 is located on the first side S1 of the air hood 160 corresponding to the fan module 150. The first air outlet 164 is disposed in the lower air flow channel C1 and is located on the second side S2 of the air hood 160 relative to the first side S1 corresponding to the heat generating module 130, and the second air outlet 166 is disposed in the lower air flow channel C1 and correspondingly The memory module 140 is located on the second side S2 of the air hood 160 and adjacent to the first air outlet 164.

In this embodiment, the number of the first air outlet 164 and the second air outlet 166 are two, and are arranged in a staggered manner on the second side S2, so that the first air outlet 164 and the second air outlet 166 are respectively Corresponding to the heat generating module 130 and the memory module 140. Accordingly, the first airflow A1 provided by the fan module 150 can flow from the air inlet 162 through the first air outlet 164 through the heat generating module 130 (shown on one of the first air outlets 164). And flowing from the air inlet 162 through the second air outlet 166 through the memory module 140 (shown on one of the second air outlets 166) to improve the heat dissipation efficiency of the electronic device 100. However, in other embodiments, the electronic device can adjust the number and position of the first air outlet 164 and the second air outlet 166 according to the number and position of the heat generating module 130 and the memory module 140. For the limit.

In addition, the air inlet 162 of the air hood 160 has a positioning post 162a, and each of the first air outlets 164 has a latching member 164a. The air guiding cover 160 can be fixed to the fan module 150 and the heat generating module 130 by the positioning post 162a and the engaging member 164a. Therefore, the air hood 160 can omit a strong bond with other parts of the electronic device 100 using additional fixing elements. More specific explanation will be given below.

4 is a schematic view of the fan module of FIG. 1. Referring to FIG. 1 and FIG. 4 , in the embodiment, the fan module 150 includes a fan frame 152 and a plurality of fans 154 . The fan 154 is disposed in the fan frame 152. The fan module 150 of the present embodiment has six fans 154 as an illustration, but in other embodiments, the number of fans can be adjusted according to requirements. The fan 154 is arranged in a row along the horizontal direction H in the fan frame 152 and faces the first electronic module 120, the heat generating module 130, the memory module 140 and the second electronic module 180, so that the fan 154 can be provided along the longitudinal direction V. The first airflow A1 and the second airflow A2 are blown to the first electronic module 120, the heat generating module 130, the memory module 140 and the second electronic module 180 to provide a heat dissipation function.

Fig. 5 is a partially enlarged cross-sectional view showing the electronic device of Fig. 1; Referring to FIG. 3 to FIG. 5, in the embodiment, the air inlet 162 of the air guiding cover 160 has three The positioning post 162a, and the fan frame 152 has three positioning holes 152a, which are located on the upper edge of the fan frame 152. However, the present invention does not limit the number and position of the positioning post 162a and the positioning hole 152a, and the embodiments can be adjusted according to requirements. . The upper edge of the fan frame 152 corresponds to the upper edge of the air inlet 162, so that the air guiding cover 160 is correspondingly inserted into the positioning hole 152a via the positioning post 162a to be assembled to the fan module 150. Therefore, the air inlet 162 of the air guiding hood 160 can accurately correspond to the fan 154 of the fan module 150 to improve the airflow concentration and prevent the air hood 160 from being displaced.

Figure 6 is a partially enlarged schematic view of the first air outlet of Figure 1. Fig. 7 is a partially enlarged cross-sectional view showing the electronic device of Fig. 1; Referring to FIG. 1 , FIG. 6 and FIG. 7 , in the embodiment, each of the heat generating modules 130 includes a heat generating component 132 , a heat dissipating component 134 , and a heat dissipating outer casing 136 . The heat generating component 132 is, for example, a central processing unit or other component that dissipates heat during operation, and the present invention does not limit the type of the heat generating component. The heating element 132 is disposed on the motherboard 110, and the heat dissipating component 134 is disposed in the heat dissipation housing 136 and thermally coupled to the heating element 132. The heat dissipating component 134 is, for example, a heat sink fin set, and the heat sink housing 136 is, for example, a sheet metal shell. However, the present invention does not limit the type and material of the heat sink component and the heat sink enclosure. Therefore, the heat generating component 132 can be dissipated by the heat dissipating component 134. However, the heat dissipation performance of the heat dissipating component 134 is limited, so that the heat generating module 130 is still in a hot state as a whole, and the first airflow A1 flowing through the heat generating module 130 is heated. Further, the memory module 140 is, for example, a memory card group, but the present invention does not limit the type of the memory module.

On the other hand, the heat dissipation housing 136 has an engaging convex portion 136a, and each of the first air outlets 164 of the air guiding cover 160 has a corresponding engaging member 164a. Clip The 164a has an engagement hook portion 164b and a pressing portion 164c. The engaging hook portion 164b is located in the first air outlet 164, and the pressing portion 164c protrudes from the first air outlet 164. Therefore, the air guiding cover 160 is fixed to the heat generating module 130 by correspondingly engaging the engaging hook portion 164b to the engaging convex portion 136a, and the air guiding cover 160 can release the engaging hook portion 164b by pressing the pressing portion 164c. The engagement relationship of the engaging convex portion 136a.

Therefore, the air hood 160 can not only guide the first airflow A1 from the fan module 150 to the heat generating module 130 and the memory module 140, but also improve the heat dissipation efficiency of the electronic device 100, and can be directly fixed to the heat generating module 130. In order to avoid the displacement of the air hood 160, the assembly and disassembly can be easily performed to facilitate the installation of the air hood 160 and the heat generating module 130 located in the lower airflow channel C1 or covered by the air hood 160 or Maintenance of the memory module 140.

8 is a schematic view of the power module and the power hood of FIG. 2. Referring to FIG. 2 and FIG. 8 , in the embodiment, the power module 120 a as the first electronic module 120 has a power opening 122 , and the power opening 122 faces the fan module 150 and faces the lower airflow channel C1 and the heat generating module 130. And the memory module 140. The power hood 170 is disposed on the power module 120a and shields part of the power source opening 122. Therefore, after the first airflow A1 flows from the first air outlet 164 and the second air outlet 166 through the heat generating module 130 and the memory module 140, the power air guiding hood 170 can block the temperature increase of the first airflow A1 from the power source. The opening 122 flows into the power module 120a.

On the other hand, in the present embodiment, the power supply hood 170 has an air inlet 172 located on one side of the power hood 170 and corresponding to the power supply opening. 122 is not covered by the power hood 170. When the air hood 160 is fixed on the fan module 150, the side of the fan module 150 and the air hood 160 and the side wall of the chassis 102 form a gap 168 (as shown in FIG. 1 and FIG. 2) to make the fan module. The third airflow A3 provided by the group 150 flows from the gap 168 to the inside of the chassis 102 without passing through the lower airflow path C1 and the upper airflow path C2. Therefore, when the power hood 170 is disposed on the power module 120a and shields part of the power source opening 122, the third airflow A3 provided by the fan module 150 flows from the gap 168 to the air inlet 172 and passes through the power hood 170. It flows into the power module 120a.

Therefore, the air inlet 172 of the power hood 170 is capable of achieving heat dissipation by guiding the third airflow A3 that has not been heated to the power module 120a. Accordingly, the power hood 170 can block the heated first airflow A1 and direct the third airflow A3 flowing directly from the fan module 150 into the power module 120a, thereby improving heat dissipation efficiency and effectively reducing the power module 120a. Operating temperature. In addition, in the embodiment, the power module 120a may also be provided with a plurality of built-in fans (not shown) to improve the heat dissipation efficiency of the power module 120a, but the invention is not limited thereto.

Figure 9 is a partially enlarged schematic view of the power hood of Figure 2; Referring to FIG. 9, in the embodiment, the power supply hood 170 also has a cable management function. Specifically, the power hood 170 has an inner surface P1 facing the power source opening 122 and an outer surface P2 facing the fan module 150. The electronic device 100 further includes a power cord 124 connecting the motherboard 110 and the power module 120a. The power line 124 is disposed on the outer surface P1 of the power hood 170 to avoid interference with the motherboard 110, and the second airflow A2 flows from the power source opening 122 into the power module via the inner surface P1. Group 120a.

Specifically, the power hood 170 has a cable hook 174 located on the outer surface P2 of the power hood 170. The power cable 124 is fixed to the power hood 170 via the cable hook 174. Accordingly, the power cord 124 can be placed between the cable hook 174 and the outer P2 to prevent the power cord 124 from directly scattering on the motherboard 110 and interfering with the operation of other electronic components on the motherboard 110. The interior of the 100 has extra space for other electronic components to be configured, and there is no need to use additional cable ties for securing the power cord 124 to the motherboard 110. Accordingly, the electronic device 100 can increase the spatial configuration.

On the other hand, please refer to FIG. 2 again. In this embodiment, the second electronic module 180 is a hard disk module 180a. The hard disk module 180a is stacked on the power module 120a and has a hard disk opening 182. The dish opening 182 faces the fan module 150. The hard disk module 180a is composed of, for example, a hard disk frame 184 and two hard disks 186, and the hard disk 186 is, for example, a large-sized hard disk (LFF) stacked side by side or stacked in the hard disk frame 184, but the present invention The composition of the hard disk module and the number and type of hard disks are not limited. Therefore, the second airflow A2 can flow to the hard disk module 180a and flow from the hard disk opening 182 into the hard disk module 180a to lower the operating temperature of the hard disk module 180a.

On the other hand, the hard disk hood 190 is disposed on the hard disk module 180a and rotatable relative to the hard disk module 180a to shield or expose the hard disk opening 182. Thus, the hard disk air deflector 190 can optionally shield or expose the hard disk opening 182 as desired. When the hard disk air hood 190 exposes the hard disk opening 182 (as shown in FIG. 2), the second air flow A2 flows into the hard disk module 180a, and The hard disk air hood 190 can be fixed to the power air hood 170 to block the first air flow A1 flowing through the heat generating module 130 from flowing into the hard disk module 180a.

Figure 10 is a partial enlarged cross-sectional view showing the power hood and the hard disk hood of Figure 2; Please refer to FIG. 9 and FIG. 10 . Specifically, in the embodiment, the hard disk air hood 190 has a fixing hook 192 , and the power hood 170 has a fixing hole 176 located at the top of the power hood 170 . When the hard disk air hood 190 is rotated relative to the hard disk module 180a to expose the hard disk opening 182 (the process is from the state of FIG. 9 to the state of FIG. 10), the hard disk air hood 190 is fixed by the hook 192. The battery is fastened to the power supply hood 170 by being fastened to the fixing hole 176.

It can be seen that the hard disk air hood 190 can be easily fixed to the power hood 170 without other fixing members, so as to prevent the hard disk hood 190 from shaking during the transportation of the electronic device 100 and hitting the other. Electronic parts. In addition, when the hard disk air guide 190 rotates relative to the hard disk module 180a to shield the hard disk opening 182, the fixing hook 192 can be easily removed from the fixing hole 176. Accordingly, the electronic device 100 has a relatively simple assembly method.

In summary, the present invention provides an electronic device in which an air hood covers a heat generating module and forms a lower air flow passage and an upper air flow passage through a partition to guide the first airflow provided by the fan module along the lower airflow. The channel flows through the heating module and the memory module, and guides the second airflow provided by the fan module to flow to the second electronic module along the upper airflow channel without the heating module, and the third module provided by the fan module The airflow flows from the gap of the air hood to the first electronic module to reduce the operating temperatures of the first electronic module, the heating module, the memory module, the second electronic module, and other electronic components, respectively. In addition, the air hood can be directly assembled to the fan module and the heat generating module by omitting additional fixing members. In addition, the power hood can block the first airflow that flows through the heating module and the memory module and flows into the power module, and the power hood has a cable management function, and the hard disk air hood can be fixed to the hard disk cover. On it. Accordingly, the electronic device has good heat dissipation efficiency and can improve the spatial arrangement degree, and has better assembly stability and a relatively simple assembly method.

Although the present invention has been disclosed in the above embodiments, it is not intended to limit the invention, and any one of ordinary skill in the art can make some modifications and refinements without departing from the spirit and scope of the invention. The scope of the invention is defined by the scope of the appended claims.

100‧‧‧Electronic devices

102‧‧‧Chassis

110‧‧‧ motherboard

120‧‧‧First electronic module

120a‧‧‧Power Module

122‧‧‧Power opening

124‧‧‧Power cord

130‧‧‧heating module

132‧‧‧heating components

134‧‧‧Heat components

136‧‧‧heating enclosure

136a‧‧‧Snap convex

140‧‧‧ memory module

150‧‧‧Fan module

152‧‧‧Fan rack

152a‧‧‧Positioning holes

154‧‧‧Fan

160‧‧‧wind hood

160a‧‧‧Baffle

162, 172‧‧ ‧ inlet

162a‧‧‧Positioning column

164‧‧‧First air outlet

164a‧‧‧Clamps

164b‧‧‧Clock hook

164c‧‧‧ Pressing Department

166‧‧‧second air outlet

168‧‧‧ gap

170‧‧‧Power air hood

174‧‧‧Management card hook

176‧‧‧Fixed holes

180‧‧‧Second electronic module

180a‧‧‧hard disk module

182‧‧‧ Hard disk opening

184‧‧‧ Hard disk rack

186‧‧‧ hard disk

190‧‧‧ hard disk air hood

192‧‧‧fixed hook

A1‧‧‧First airflow

A2‧‧‧second airflow

A3‧‧‧ third airflow

B‧‧‧Back side

C1‧‧‧lower airflow channel

C2‧‧‧Upstream airflow channel

F‧‧‧ front side

H‧‧‧ Landscape

Inside P1‧‧‧

Outside P2‧‧‧

S‧‧‧ accommodating space

S1‧‧‧ first side

S2‧‧‧ second side

V‧‧‧ portrait

1 is a schematic diagram of an electronic device according to an embodiment of the present invention.

2 is a schematic view of the electronic device of FIG. 1 from another perspective.

3 is a schematic view of the air hood of FIG. 1.

4 is a schematic view of the fan module of FIG. 1.

Fig. 5 is a partially enlarged cross-sectional view showing the electronic device of Fig. 1;

Figure 6 is a partially enlarged schematic view of the first air outlet of Figure 1.

Fig. 7 is a partially enlarged cross-sectional view showing the electronic device of Fig. 1;

8 is a schematic view of the power module and the power hood of FIG. 2.

Figure 9 is a partially enlarged schematic view of the power hood of Figure 2;

Figure 10 is a partial enlarged cross-sectional view showing the power hood and the hard disk hood of Figure 2;

100‧‧‧Electronic devices

102‧‧‧Chassis

110‧‧‧ motherboard

120‧‧‧First electronic module

120a‧‧‧Power Module

130‧‧‧heating module

132‧‧‧heating components

140‧‧‧ memory module

150‧‧‧Fan module

160‧‧‧wind hood

160a‧‧‧Baffle

162‧‧‧air inlet

164‧‧‧First air outlet

166‧‧‧second air outlet

168‧‧‧ gap

180‧‧‧Second electronic module

180a‧‧‧hard disk module

190‧‧‧ hard disk air hood

A1‧‧‧First airflow

A2‧‧‧second airflow

B‧‧‧ Back area

F‧‧‧ front area

H‧‧‧ Landscape

S‧‧‧ accommodating space

S1‧‧‧ first side

S2‧‧‧ second side

V‧‧‧ portrait

Claims (14)

An electronic device comprising: a motherboard; a plurality of heat generating modules disposed on the motherboard in a lateral direction; a first electronic module disposed on a front side of the motherboard along a longitudinal direction perpendicular to the lateral direction; a second electronic module is disposed on the front side of the motherboard and stacked on the first electronic module; a fan module is located along a lateral direction of the motherboard relative to the front side and facing the rear a heat generating module and the second electronic module; and a windshield covering the heat generating modules and having a partition extending from the fan module to the first electronic module to be in the partition Forming a lower airflow channel with the motherboard, and forming an upper airflow channel above the partition, wherein the air hood guides a first airflow provided by the fan module to flow along the lower airflow channel The heat generating module guides a second airflow provided by the fan module to the second electronic module along the upper airflow channel without the heat generating module. The electronic device of claim 1, further comprising: a power hood, wherein the first electronic module is a power module, the power module has a power opening, the power opening facing the fan The module is disposed facing the lower airflow channel and the heat generating modules, and the power air guiding cover is disposed on the power module and shields part of the power opening to block the flow of the first airflow flowing through the heat generating modules Power module. An electronic device as claimed in claim 2, wherein the electric device The air hood has an air inlet, located at one side of the power hood and corresponding to a portion of the power opening that is not covered by the power hood, so that the third airflow provided by the fan module Flowing from a gap of the air hood to the air inlet and flowing into the power module via the power hood. The electronic device of claim 2, further comprising: a power cord connecting the motherboard and the power module, wherein the power hood has an inner surface facing the power opening and facing the fan module An outer side of the group is disposed outside the power hood to avoid interference with the motherboard, and the second airflow flows from the power opening through the inner surface into the power module. The electronic device of claim 4, wherein the power hood has a cable hook located outside the power hood, and the power cable is fixed to the power cable via the cable hook Power supply hood. The electronic device of claim 1, wherein the air hood includes an air inlet and a plurality of first air outlets, and the air inlet is located on a first side of the air hood corresponding to the fan module The first air outlets are disposed on the lower air flow channel and are located on a second side of the air hood relative to the first side corresponding to the heat generating modules, so that the first air flow can be from the air inlet The heat generating modules are flowed through the first air outlets. The electronic device of claim 6, wherein the fan module comprises a fan frame and a plurality of fans, wherein the fan is disposed in the fan frame, the fan frame has at least one positioning hole, and the air inlet has At least one positioning post, the air hood is assembled to the fan module by correspondingly penetrating the positioning post into the positioning hole. The electronic device of claim 6, wherein each of the heat generating modules includes a heat generating component, a heat dissipating component, and a heat dissipating component disposed in the heat dissipating casing and thermally coupled to the heat generating component. The heat dissipating outer casing has a latching convex portion, and each of the first air outlets has a corresponding engaging member, and the engaging member has a latching hook portion, and the air guiding cover is correspondingly engaged by the engaging hook portions Fixing to the heat generating modules to the engaging protrusions. The electronic device of claim 8, wherein each of the engaging members has a pressing portion protruding from the first air outlet, and the air guiding cover releases the cards by pressing the pressing portion. The engaging relationship between the hook portion and the engaging convex portions. The electronic device of claim 6, further comprising: at least one memory module disposed along the lateral direction of the motherboard and adjacent to the heat generating module, wherein the air guiding cover further comprises at least a second An air outlet is disposed on the lower airflow passage and is located on the second side of the air hood corresponding to the memory module and adjacent to the first air outlet, so that the first airflow can pass through the air inlet The two air outlets flow through the memory module. The electronic device of claim 10, wherein the number of the heat generating modules and the memory modules are two and are staggered with each other and disposed on the motherboard, the first air outlets and The number of the second air outlets is two and is staggered to each other to be located on the second side, so that the first air outlets and the second air outlets respectively correspond to the heat generating modules and the memory Module. For example, the electronic device described in claim 1 further includes: a hard disk air hood, wherein the second electronic module is a hard disk module, the hard disk module has a hard disk opening, the hard disk opening faces the fan module, and the hard disk air hood is disposed on The hard disk module is rotatable relative to the hard disk module to shield or expose the hard disk opening, wherein the second air current flows into the hard disk mode when the hard disk air guiding cover exposes the hard disk opening And the hard disk air hood can be fixed to the power air hood to block the first airflow flowing through the heat generating modules from flowing into the hard disk module. The electronic device of claim 12, wherein the hard disk air hood has a fixed hook, the power hood having a fixing hole located at a top of one of the power hoods, when the hard When the disk air hood exposes the hard disk opening, the hard disk air hood is fixed to the power air hood by engaging the fixing hook to the fixing hole. The electronic device of claim 1, further comprising: a chassis having an accommodating space, wherein the motherboard and the fan module are disposed in the chassis to enable the first airflow and the second airflow The air hood flows through the hood and flows out of the chassis to dissipate heat.