CN203422704U - Novel high-temperature energy saving type server case air draft and heat dissipation system - Google Patents

Abstract

The utility model relates to the technical field of servers of computers, in particular to a novel high-temperature energy saving type server case air draft and heat dissipation system. The novel high-temperature energy saving type server case air draft and heat dissipation system comprises a high-temperature resistant all-in-one machine case, a heat dissipation system, a server node system and a power system, wherein the high-temperature resistant all-in-one machine case, the heat dissipation system, the server node system and the power system are respectively provided with a power pinboard inside. The heat dissipation system is located on the rear portion of the high-temperature resistant all-in-one machine case, the server node system is arranged on the front portion of the high-temperature resistant all-in-one machine case, the server node system is in plug-in connection with the high-temperature resistant all-in-one machine case, the power system is located on the bottom portion of the high-temperature resistant all-in-one machine case, and the power pinboard in the heat dissipation system, the power pinboard in the server node system, the power pinboard in the power system are all connected with the power pinboard in the high-temperature resistant all-in-one machine case. According to the novel high-temperature energy saving type server case air draft and heat dissipation system, heat sources in the server case are reduced, the density of the server is improved, reasonable air flues are formed, and the system can adapt to higher environment temperature and achieve faster and better heat dissipation effects under the condition that the density of the server is increased.

Description

A new type of high-temperature energy-saving server chassis ventilation cooling system

technical field

The utility model relates to the technical field of servers in computers, in particular to a novel high-temperature energy-saving server chassis ventilation cooling system.

Background technique

At present, server products and rack-mounted servers all include motherboards, power supplies, hard disks, and fans. These components form a whole. At present, most fans are located in the front of the middle of the chassis, blowing the heat generated by the server from front to back. This structure can only adapt to the ambient temperature of 35 ℃. For server products with more complex structures and higher space density, the current cooling fans cannot adapt to the ambient temperature exceeding 35°C, and cannot achieve the purpose of heat dissipation in a timely and rapid manner. Excessively high temperatures will affect the service life of components and increase The cost of replacing server parts. When a traditional server fan fails, it is necessary to turn off the power, turn on the server to replace the fan, and then restart the server to run, which will greatly reduce work efficiency. If the server is performing computing tasks and the fan is not replaced in time, the server will be down. computer, resulting in computing interruption, file loss and other problems. Simultaneously, the operation steps are loaded down with trivial details. At present, there is no effective product to solve the above problems.

Utility model content

The technical problem solved by the utility model is to provide a new type of high-temperature energy-saving server chassis ventilation and heat dissipation system. The utility model transforms the traditional server structure, separates the power supply and the fan, reduces the heat source in the server chassis, and The density of the server is increased, and a reasonable air duct is formed at the same time. When the density of the server is increased, it can adapt to a higher ambient temperature and achieve faster and better heat dissipation.

In order to solve the above-mentioned technical problems, the utility model provides a novel high-temperature energy-saving server case ventilation cooling system, including: a high-temperature-resistant all-in-one machine case, a heat dissipation system, a server node system, and a power supply system; The heat dissipation system, the server node system and the power supply system are all equipped with a power adapter board; The board is connected to the power adapter board in the case of the high-temperature-resistant all-in-one machine; the server node system is located at the front of the case of the high-temperature-resistant all-in-one machine The chassis is plug-in connected, and the power adapter board in the server node system is connected to the power adapter board in the high-temperature-resistant all-in-one machine chassis; the power supply system is located in the high-temperature-resistant all-in-one machine chassis At the bottom, the power adapter board in the power supply system is connected to the power adapter board in the chassis of the high temperature resistant all-in-one machine.

Preferably, a set of the heat dissipation system includes three fans, a fan fixing bracket and the power adapter board; the fans are connected to the fan fixing bracket and the power adapter board.

More preferably, the server node system includes a server chassis, a mainboard, a hard disk, and the power adapter board; the hard disk and the power adapter board are arranged on the mainboard, and the mainboard, the hard disk, and the The power adapter board is arranged in the server chassis.

More preferably, one or more servers are provided with a set of cooling systems.

More preferably, two servers are provided with a set of cooling systems.

More preferably, the server node system is arranged at an angle to the horizontal.

More preferably, the angle includes 0°-90°.

More preferably, the angle includes 0°, 30°, 45°, 60° and 90°.

More preferably, when the angle is 0°, the server node system is set horizontally; when the angle is 90°, the server node system is set vertically; when the angle is 45°, the server node system is set vertically; The server node system described above is set at a slant.

More preferably, the angle includes 0° and 90°.

The working process of the utility model is: the heat dissipation system is located at the rear of the high-temperature-resistant all-in-one machine chassis, preferably the server node system is inserted horizontally from the front of the high-temperature-resistant all-in-one machine chassis, and is perpendicular to the heat dissipation system, and is realized by sending air backward through the heat dissipation system Cooling of the server node system.

The process of replacing the fan in the utility model is: firstly remove the fan cover of the fan fixing bracket, unplug the cable inserted on the power adapter board of the fan to be replaced, cut off the power supply, and then remove the fan fixing bracket of a single fan, Take out the fan and replace it. After the replacement, fix the fan fixing bracket of a single fan, plug in the cable on the fan power adapter board, and supply power again.

Compared with the prior art, the utility model has the following beneficial effects:

The utility model provides a new type of high-temperature energy-saving server chassis ventilation and heat dissipation system. The utility model transforms the traditional server structure, separates the power supply and the fan, and provides power and heat dissipation for multiple servers in a centralized manner. The fans provide centralized heat dissipation, which is more efficient than traditional server cooling alone, which reduces the heat source in the server chassis and increases the density of the server. At the same time, it forms a reasonable air duct, which can adapt to higher server density Ambient temperature for faster and better heat dissipation. Traditional servers generally require an operating temperature of 35°C. The integrated server of the utility model can operate normally at an ambient temperature of 45°C, which can help data centers save about 50% of daily electricity expenses. With the integrated server of the utility model, the fan can be replaced in the working state of the server, which avoids the cumbersome steps of shutting down and restarting the server.

Description of drawings

FIG. 1 exemplarily shows a schematic structural diagram of a traditional server;

Fig. 2 exemplarily shows the structural representation of the server chassis of the present utility model;

Fig. 3 exemplarily shows a schematic structural view of the integrated server chassis ventilation cooling system of the present invention;

Fig. 4 exemplarily shows a structural schematic diagram of the integrated server power supply system of the present invention.

Fig. 5 exemplarily shows a schematic diagram of the overall structure of the integrated server chassis of the present invention.

The reference signs shown in Figures 1 to 5 are as follows: 1. High temperature resistant all-in-one machine chassis, 2. Cooling system, 3. Server node system, 4. Power supply system, 5. Fan, 6. Fan fixing bracket, 7. Power adapter board, 8, server case, 9, motherboard, 10, hard disk.

Detailed ways

In order to better understand the technical problems solved by the utility model and the technical solutions provided, the utility model will be further described in detail below in conjunction with the accompanying drawings and embodiments. The specific embodiments described here are only used to explain the implementation of the utility model, but are not used to limit the utility model.

In a preferred embodiment, compared with the structure of the traditional server in Fig. 1, Fig. 2 exemplarily shows the structure of the server chassis of the present utility model, and Fig. 3 exemplarily shows the structure of the utility model integrated server chassis The structural schematic diagram of the ventilation cooling system and Figure 4 exemplarily show the overall structural schematic diagram of the integrated server chassis of the present invention; including: a high temperature resistant integrated machine chassis 1, a cooling system 2, a server node system 3 and a power supply system 4; The high-temperature-resistant all-in-one machine chassis 1, the heat dissipation system 2, the server node system 3 and the power supply system 4 are all equipped with a power adapter board 7; the heat dissipation system 2 is located in the high-temperature-resistant all-in-one machine chassis 1 at the rear of the cooling system 2, the power adapter board 7 in the heat dissipation system 2 is connected to the power adapter board 7 in the high-temperature-resistant all-in-one machine chassis 1 for power supply; the server node system 3 is located in the The front position of the high-temperature all-in-one machine chassis 1, the server node system 3 is connected to the high-temperature-resistant all-in-one machine The power adapter board 7 in the all-in-one machine case 1 is connected to supply power; the power supply system 4 is located at the bottom of the high-temperature-resistant all-in-one machine case 1, and the power adapter plate 7 in the power supply system 4 is connected to the The power adapter board 7 in the case 1 of the high-temperature-resistant all-in-one machine is connected to supply power.

In a more preferred embodiment, a set of said cooling system 2 includes three 120x38 12V fans 5, a fan fixing bracket 6 and said power adapter board 7; said fan 5 is connected with said fan fixing bracket 6 and said The power adapter board 7 is connected to each other.

In a more preferred embodiment, the server node system 3 includes a server chassis 8, a motherboard 9, a hard disk 10 and the power adapter board 7; the hard disk 10 and the power adapter board 7 are arranged on the motherboard 9, the main board 9, the hard disk 10 and the power adapter board 7 are arranged in the server chassis 8.

In a more preferred embodiment, more than one server is equipped with a set of cooling systems 2 .

In a more preferred embodiment, two servers are equipped with a set of cooling systems 2 .

In a more preferred embodiment, said server node system 3 is arranged at an angle to the horizontal.

In a more preferred embodiment, the angle includes 0°-90°.

In a more preferred embodiment, the angle includes 0°, 30°, 45°, 60°, 90°.

In a more preferred embodiment, when the angle is 0°, the server node system 3 is set horizontally; when the angle is 90°, the server node system 3 is set vertically; when the angle When it is 45°, the server node system 3 is set on an incline.

In a more preferred embodiment, the angles of 0° and 90° are common and work best.

Concrete embodiment:

The working process of the utility model is: the heat dissipation system is located at the rear of the high-temperature-resistant all-in-one machine chassis, preferably the server node system is inserted horizontally from the front of the high-temperature-resistant all-in-one machine chassis, and is perpendicular to the heat dissipation system, and is realized by sending air backward through the heat dissipation system Cooling of the server node system.

The process of replacing the fan in the utility model is: firstly remove the fan cover of the fan fixing bracket, unplug the cable inserted on the power adapter board of the fan to be replaced, cut off the power supply, and then remove the fan fixing bracket of a single fan, Take out the fan and replace it. After the replacement, fix the fan fixing bracket of a single fan, plug in the cable on the fan power adapter board, and supply power again.

The utility model has been described in detail above by preferred and specific embodiments, but those skilled in the art should understand that the utility model is not limited to the above-mentioned embodiments, and all within the basic principles of the utility model, all made Any modification, combination and equivalent replacement, etc., are included in the protection scope of the present utility model.

Claims (10)

1. a new type high temperature energy-conserving server cabinet exhaust cooling system, is characterized in that, comprising: high temperature resistant all-in-one cabinet, cooling system, server node system and power-supply system; In described high temperature resistant all-in-one cabinet, described cooling system, described server node system and described power-supply system, be equipped with Power conversion board; Described cooling system is positioned at the rear portion of described high temperature resistant all-in-one cabinet, and the described Power conversion board in described cooling system is connected with the described Power conversion board in described high temperature resistant all-in-one cabinet; Described server node system is located at the forward position of described high temperature resistant all-in-one cabinet, described server node system interleaves formula with described high temperature resistant all-in-one cabinet and is connected, and the intrasystem described Power conversion board of described server node is connected with the described Power conversion board in described high temperature resistant all-in-one cabinet; Described power-supply system is positioned at the bottom of described high temperature resistant all-in-one cabinet, and the described Power conversion board in described power-supply system is connected with the described Power conversion board in described high temperature resistant all-in-one cabinet.

2. new type high temperature energy-conserving server cabinet exhaust cooling system according to claim 1, is characterized in that, described in one group, cooling system comprises 3 fans, fan fixing rack and described Power conversion board; Described fan is connected with described Power conversion board with described fan fixing rack.

3. new type high temperature energy-conserving server cabinet exhaust cooling system according to claim 1, is characterized in that, described server node system comprises machine box for server, mainboard, hard disk and described Power conversion board; Described hard disk and described Power conversion board are located on described mainboard, and described mainboard, described hard disk and described Power conversion board are located in described machine box for server.

4. new type high temperature energy-conserving server cabinet exhaust cooling system according to claim 1, is characterized in that, the above server be provided with one group described in cooling system.

5. new type high temperature energy-conserving server cabinet exhaust cooling system according to claim 1, is characterized in that, two described servers be provided with one group described in cooling system.

6. new type high temperature energy-conserving server cabinet exhaust cooling system according to claim 1, is characterized in that, described server node system and level are angle setting.

7. new type high temperature energy-conserving server cabinet exhaust cooling system according to claim 6, is characterized in that, described angle comprises 0 °～90 °.

8. new type high temperature energy-conserving server cabinet exhaust cooling system according to claim 7, is characterized in that, described angle comprises 0 °, 30 °, 45 °, 60 ° or 90 °.

9. new type high temperature energy-conserving server cabinet exhaust cooling system according to claim 8, is characterized in that, when the angle ranging from 0 °, described server node system is for being horizontally disposed with; While the angle ranging from 90 °, described server node system is vertically to arrange; When the angle ranging from 45 °, described server node system is for being obliquely installed.

10. new type high temperature energy-conserving server cabinet exhaust cooling system according to claim 7, is characterized in that, described angle comprises 0 ° and 90 °.

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