CN210247356U - Emergent heat abstractor of container data center - Google Patents

Abstract

The utility model provides an emergent heat abstractor of container data center, include: dividing the space in the container into a cold channel area, a hot channel area and a cabinet area, wherein the cabinet area is arranged between the cold channel area and the hot channel area; the cold channel area is provided with a fan; the hot channel area is provided with an exhaust fan; the cabinet area is provided with a temperature sensor and a processor, and the temperature sensor is connected with the input end of the processor; the output end of the processor is connected with the induced fan controller and the exhaust fan controller. The utility model provides an emergent heat abstractor of container data center can in time dispel the heat to the container after refrigerating system became invalid, makes data center can normal operating, has strengthened container data center's stability and result of use.

Description

Emergent heat abstractor of container data center

Technical Field

The utility model belongs to the technical field of big data analysis, concretely relates to emergent heat abstractor of container data center.

Background

With the rapid development of the electronic information industry, the development of data centers is also entering a new stage. The container data center is a standard module which can be constructed as a data center, and IT facilities such as calculation, storage, network resources and the like are designed into a container. Under the stream of big data construction, more and more container data centers are put into use, and for the convenience of transportation and convenient deployment, the container data centers are more and more widely applied.

Because the calculation amount of the container data center is extremely large, and the environment is relatively closed, the heat dissipation is a key factor influencing the performance of the container data center. At present, most of container data centers adopt air conditioners for heat dissipation, a plurality of air conditioners are arranged in a container, and a refrigeration controller is used for uniformly controlling the plurality of air conditioners. Once the refrigeration controller or the air conditioner fails, the temperature in the container rapidly rises, and all operations of the container data center must be stopped to repair the refrigeration system in an emergency. If the operation of the container data center is stopped when the refrigeration system fails in time, the damage of the operation equipment is likely to be caused. However, the sudden shutdown of the data center also causes serious problems of operation interruption, even data loss and the like in practical application, and the customer experience is not good.

Based on the above technical problems, there is an urgent need for a backup heat dissipation scheme to ensure the operation of the container data center during the failure of the refrigeration system.

SUMMERY OF THE UTILITY MODEL

The above-mentioned not enough to prior art, the utility model provides an emergent heat abstractor of container data center to solve above-mentioned technical problem.

The utility model provides an emergent heat abstractor of container data center, include: dividing the space in the container into a cold channel area, a hot channel area and a cabinet area, wherein the cabinet area is arranged between the cold channel area and the hot channel area; the cold channel area is provided with a fan; the hot channel area is provided with an exhaust fan; the cabinet area is provided with a temperature sensor and a processor, and the temperature sensor is connected with the input end of the processor; the output end of the processor is connected with the induced fan controller and the exhaust fan controller.

Furthermore, a power distribution cabinet, a cabinet and an inter-row air conditioner are arranged in the cabinet body area, and the power distribution cabinet, the cabinet and the inter-row air conditioner are consistent in height and are arranged in parallel to the short edge of the container; gaps on one sides of the power distribution cabinet, the cabinet and the inter-row air conditioners close to the cold channel area are closed; a sealing wall is arranged between the upper part of the cabinet body area and the top wall of the container, and the space between the cabinet body area and the container is divided into a cold channel area and a hot channel area.

Further, the inter-column air conditioner is connected with the processor.

Furthermore, the sealing wall is arranged on the extending surface of the side surface of the cabinet area connected with the cold channel area, and the sealing wall is a heat insulation sealing wall.

Furthermore, the induced fan and the exhaust fan are both square shells, and the top of each square shell is provided with a rain cover which forms an included angle of 45 degrees with the fan.

Furthermore, a layer of insect-proof net is fixed at the air port of the square shell.

Furthermore, a gravity type air check valve is arranged at an air port of the square shell.

Furthermore, a fire-fighting cabinet is also arranged in the container.

Furthermore, three flange wire inlets are arranged on the right side of the container.

Furthermore, the side surfaces of two ends of the container are provided with weathertight doors.

The utility model has the advantages that,

the utility model provides an emergent heat abstractor of container data center, through dividing the container inner space into cold passageway district, hot passageway district and cabinet body district, and set up the induced fan in cold passageway district, set up the exhaust fan in hot passageway district, set up temperature sensor and treater in cabinet body district, after container data center refrigerating system became invalid, the temperature that temperature sensor gathered cabinet body district is higher than behind the temperature threshold value, treater control induced fan and exhaust fan start, through introducing cold wind, the hot-blast heat that realizes in the container of discharge is along with the air fast and is dispelled. During the repair period of the refrigeration system, the data center is cooled by the emergency cooling device, and the data center can work normally. The utility model provides an emergent heat abstractor of container data center can in time dispel the heat to the container after refrigerating system became invalid, makes data center can normal operating, has strengthened container data center's stability and result of use.

Furthermore, the utility model relates to a principle is reliable, and simple structure has very extensive application prospect.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an emergency heat sink device for a container data center according to an embodiment of the present application;

FIG. 2 is a schematic structural diagram of an emergency heat sink device of a container data center according to an embodiment of the present application;

wherein, 1, a cold channel area; 2. a hot channel region; 3. a cabinet area; 4. a fan guide; 5. an exhaust fan; 6. a fire-fighting cabinet; 7. weather-tight door.

Detailed Description

In order to make the technical solutions in the present invention better understood, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, but not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts shall belong to the protection scope of the present invention.

It should be noted that, in the present invention, the embodiments and features of the embodiments may be combined with each other without conflict.

The present invention will be described in detail below with reference to the accompanying drawings in conjunction with embodiments.

Example 1

As shown in fig. 1, the present embodiment provides an emergency heat sink device for a container data center. The interior region of the container is divided into a cold aisle region 1, a hot aisle region 2 and a cabinet region 3. The cabinet area 3 is formed by arranging data center core equipment (power distribution cabinets, cabinets and the like) and air conditioners between columns in rows, and gaps vertical to cold and hot channels are formed between adjacent rows of equipment. The cold channel area 1 end of the gap is sealed by a sealing plate or a sliding door. And a sliding door is arranged at the joint position of the cold channel area 1 and the hot channel area 2 to divide the two areas. Referring to fig. 2, the area between the top of the cabinet section 3 and the top wall of the container is provided with an insulating sealing wall, and the insulating material is selected to reduce the direct heat exchange in the area. The upper part of the container side wall of the cold passage area 1 is provided with a draught fan 4, and the upper part of the container side wall of the hot passage area 2 is provided with an exhaust fan 5. A temperature sensor and a processor are arranged in the cabinet area 3, the temperature sensor is connected with the input end of the processor, and the output end of the processor is connected with a guide fan controller and an exhaust fan controller.

The temperature sensor sends the temperature in the cabinet body area to the processor, and after the processor judges that the temperature is too high (exceeds a preset threshold value), the processor respectively sends a starting command to the induced fan controller and the exhaust fan controller to control the induced fan and the exhaust fan to start. Meanwhile, the processor calculates the unit air quantity required by heat dissipation according to the real-time temperature, calculates the rotating speeds of the induced fan and the exhaust fan according to the unit air quantity and the fan parameters, and respectively sends corresponding rotating speeds to the induced fan controller and the exhaust fan controller, so that the rotating speeds of the induced fan and the exhaust fan are adjusted according to the temperature, and the energy consumption of the fan is reduced.

Example 2

As shown in fig. 1, the present embodiment provides an emergency heat sink device for a container data center. The interior region of the container is divided into a cold aisle region 1, a hot aisle region 2 and a cabinet region 3. As can be seen from fig. 1, the cabinet area 3 is formed by arranging data center core equipment (power distribution cabinets, machine cabinets, etc.) and inter-row air conditioners in rows, and gaps perpendicular to the cold and hot channels are formed between adjacent rows of equipment. The cold channel area 1 end of the gap is sealed by a sealing plate or a sliding door. And a sliding door is arranged at the joint position of the cold channel area 1 and the hot channel area 2 to divide the two areas. Referring to fig. 2, the area between the top of the cabinet section 3 and the top wall of the container is provided with an insulating sealing wall, and the insulating material is selected to reduce the direct heat exchange in the area. The container side wall upper portion of cold passageway district 1 sets up induced fan 4, and 2 container side wall upper portions of hot passageway district set up exhaust fan 5, and induced fan 4 and the exhaust fan 5 that set up relatively are a set of fan, and a set of fan corresponds a equipment. A temperature sensor and a processor are arranged in the cabinet area 3, the temperature sensor and the air conditioner management end are connected with the input end of the processor, and the output end of the processor is connected with a draught fan controller and an exhaust fan controller.

The air conditioner management end screens out the abnormal operation parameters of a certain air conditioner from the air conditioner management information (marked with the operation parameters of the air conditioner identification codes) in real time, and after the air conditioner management information received by the processor is determined to be invalid, the processor starts a group of fans (an induced fan 4 and an exhaust fan 5) at the corresponding position of the air conditioner.

In addition, if the temperature collected by the temperature sensor still exceeds the preset threshold value under the condition that all the air conditioners normally operate, the processor controls the air inducing fan 4 and the exhaust fan 5 to be started.

Example 3

The embodiment provides an emergent heat abstractor of container data center, divides the container interior region into cold passageway district 1, hot passageway district 2 and cabinet body district 3. As can be seen from fig. 1, the cabinet area 3 is formed by arranging data center core equipment (power distribution cabinets, machine cabinets, etc.) and inter-row air conditioners in rows, and gaps perpendicular to the cold and hot channels are formed between adjacent rows of equipment. The cold channel area 1 end of the gap is sealed by a sealing plate or a sliding door. And a sliding door is arranged at the joint position of the cold channel area 1 and the hot channel area 2 to divide the two areas. Referring to fig. 2, the area between the top of the cabinet section 3 and the top wall of the container is provided with an insulating sealing wall, and the insulating material is selected to reduce the direct heat exchange in the area. The container side wall upper portion of cold passageway district 1 sets up induced fan 4, and 2 container side wall upper portions of hot passageway district set up exhaust fan 5, and induced fan 4 and the exhaust fan 5 that set up relatively are a set of fan, and a set of fan corresponds a equipment. A temperature sensor and a processor are arranged in the cabinet area 3, the temperature sensor and the air conditioner management end are connected with the input end of the processor, and the output end of the processor is connected with a draught fan controller and an exhaust fan controller. The induced fan and the exhaust fan are both square shells, and the top of each square shell is provided with a rain-proof cover which forms an included angle of 45 degrees with the fan. And a layer of insect-proof net is fixed at the air port of the square shell and used for placing insects to fly into the container. A gravity type non-return air valve or an air valve with an electric actuator is arranged at an air port of the square shell, so that the container is ensured to be isolated from the outside when the fan is not opened. The container is also provided with a fire-fighting cabinet and three flange wire inlets. The side surfaces of two ends of the container are provided with weather-tight doors, the container is used under the conditions of container access and emergency, and the data center is closed when in normal operation; during normal maintenance, workers pass through the isolation area through the weather-tight door on the right side and then enter the cabinet area 3.

The air conditioner management end screens out the abnormal operation parameters of a certain air conditioner from the air conditioner management information (marked with the operation parameters of the air conditioner identification codes) in real time, and after the air conditioner management information received by the processor is determined to be invalid, the processor starts a group of fans (an induced fan 4 and an exhaust fan 5) at the corresponding position of the air conditioner.

In addition, if the temperature collected by the temperature sensor still exceeds the preset threshold value under the condition that all the air conditioners normally operate, the processor controls the air inducing fan 4 and the exhaust fan 5 to be started.

Although the present invention has been described in detail by referring to the drawings in conjunction with the preferred embodiments, the present invention is not limited thereto. Various equivalent modifications or substitutions can be made on the embodiments of the present invention by those skilled in the art without departing from the spirit and substance of the present invention, and these modifications or substitutions are intended to be within the scope of the present invention/any person skilled in the art can easily conceive of changes or substitutions within the technical scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (10)

1. The utility model provides an emergent heat abstractor of container data center which characterized in that includes: dividing the space in the container into a cold channel area, a hot channel area and a cabinet area, wherein the cabinet area is arranged between the cold channel area and the hot channel area; the cold channel area is provided with a fan; the hot channel area is provided with an exhaust fan; the cabinet area is provided with a temperature sensor and a processor, and the temperature sensor is connected with the input end of the processor; the output end of the processor is connected with the induced fan controller and the exhaust fan controller.

2. The container data center emergency heat dissipation device of claim 1, wherein a power distribution cabinet, a cabinet and an inter-row air conditioner are arranged in the cabinet area, and the power distribution cabinet, the cabinet and the inter-row air conditioner are consistent in height and are all arranged in parallel to a short edge of the container; gaps on one sides of the power distribution cabinet, the cabinet and the inter-row air conditioners close to the cold channel area are closed; a sealing wall is arranged between the upper part of the cabinet body area and the top wall of the container, and the space between the cabinet body area and the container is divided into a cold channel area and a hot channel area.

3. The container data center emergency heat sink of claim 2, wherein the inter-column air conditioner is connected to a processor.

4. The container data center emergency heat sink of claim 2, wherein the enclosure wall is disposed on a side extension of the cabinet region that interfaces with the cold aisle region, and the enclosure wall is a heat insulating enclosure wall.

5. The container data center emergency heat dissipation device of claim 1, wherein the induced fan and the exhaust fan are both square shells, and a rain cover forming an included angle of 45 degrees with the fan is arranged at the top of each square shell.

6. The container data center emergency heat sink of claim 5, wherein a layer of insect screen is secured to the square housing at the air opening.

7. The container data center emergency heat sink of claim 5, wherein a gravity check air valve is disposed at an air port of the square housing.

8. The container data center emergency heat sink of claim 1, wherein the container is further provided with a fire cabinet.

9. The container data center emergency heat sink of claim 1, wherein three flanged inlets are mounted to the right side of the container.

10. The container data center emergency heat sink of claim 1, wherein weathertight doors are provided on both sides of the container.

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