CN211909536U - Intelligent test cloud platform based on multi-data source switching - Google Patents

Abstract

The utility model relates to a smart test cloud platform based on multi-data source switching, which comprises a box body, wherein a box door is hinged on one side surface of the box body, and a sealing strip is arranged at the butt joint of the box door and the box body; the box body is internally provided with a plurality of layers of horizontal mounting plates for mounting hardware facilities, the top end of the box body is communicated with an exhaust pipe, and a first fan is also arranged in the exhaust pipe at the communication part of the exhaust pipe and the box body; the bottom end of the box body is communicated with a gas pipe, and a second fan is arranged inside one end of the gas pipe communicated with the box body; the outer wall of the box body is also provided with a cooling chamber, a cooling pipe is arranged in the cooling chamber, the cooling pipe is connected with a heat exchange device, and cooling liquid flows in the cooling pipe in a circulating manner; the top end of the cooling chamber is communicated with the air exhaust pipe, and the bottom end of the cooling chamber is communicated with the gas pipe. The utility model discloses have the effect that improves the interior radiating efficiency of experimental cloud platform box.

Description

Intelligent test cloud platform based on multi-data source switching

Technical Field

The utility model belongs to the technical field of the technique of the experimental cloud platform of data and specifically relates to an experimental cloud platform of wisdom based on switching of multidata source is related to.

Background

With the rapid development of scientific technology and the high quality requirement of product manufacturing, the product pursues comprehension and concretization of data acquisition in the production process, namely, more and more data sources need to be acquired and accessed in the measurement, calculation and evaluation process. Data is segmented in large-scale application, and a plurality of database instances are adopted for management, so that the horizontal flexibility of the system can be effectively improved. Such a scheme differs from the conventional single data instance scheme in that the program dynamically determines which database instance to store data in and which database to retrieve data from at run time based on the current request and system state. The speed and stability of the system for processing the big data are greatly related to the performance of the whole hardware facilities such as the server, however, in a test platform or the system, the hardware facilities such as the server can generate a large amount of heat in the working process, and if the heat is not dissipated in time, the whole test platform or the whole system can be paralyzed.

Notice No. CN 206674412U's chinese patent discloses a wall-hanging healthy big data server cabinet, including server cabinet main part, radiator fan No. one is installed to the left end of server cabinet main part upper surface, and the right-hand member of server cabinet main part upper surface installs radiator fan No. two, the left end of server cabinet main part leading flank is connected with the pivot No. one, and the left end of pivot installs the cabinet door No. one, the left side of cabinet door internal surface is provided with the card hole, and the inboard of cabinet door is connected with the sealing strip.

In the above scheme, the heat dissipation columns, the heat dissipation holes, the heat dissipation fan, the water cooling pipe, the heat absorption plate and the air suction fan are adopted, so that the circulation of air inside the server cabinet can be accelerated, and the heat dissipation rate is accelerated. In the scheme, however, a large number of heat dissipation holes are distributed on the top surface and the bottom surface of the server cabinet main body, and dust impurities in the air can enter the server cabinet while the air suction fan sucks the air into the server cabinet; when long-term use, the radiating effect of hardware facilities can be influenced to a large amount of dust that accumulates in the server cabinet.

SUMMERY OF THE UTILITY MODEL

Not enough to prior art exists, the utility model aims at providing a can improve hardware facilities radiating effect's such as servers experimental cloud platform of wisdom.

The above technical purpose of the present invention can be achieved by the following technical solutions: a smart test cloud platform based on multi-data source switching comprises a box body, wherein a box door is hinged to one side face of the box body, and a sealing strip is further arranged at the position where the box door is abutted to the box body; the box body is internally provided with a plurality of layers of horizontal mounting plates for mounting hardware facilities, the top end of the box body is communicated with an exhaust pipe, and a first fan is further arranged in the exhaust pipe at the communication part of the exhaust pipe and the box body; the bottom end of the box body is communicated with a gas pipe, and a second fan is arranged inside one end of the gas pipe communicated with the box body; the outer wall of the box body is also provided with a cooling chamber, a cooling pipe is arranged in the cooling chamber, the cooling pipe is connected with a heat exchange device, and cooling liquid flows in the cooling pipe in a circulating manner; the top end of the cooling chamber is communicated with the air exhaust pipe, and the bottom end of the cooling chamber is communicated with the air delivery pipe.

By adopting the technical scheme, various hardware facilities such as the server and the like emit a large amount of heat in the working process. In the case, the hot air flows upward; the first fan pumps hot air out of the air pumping pipe and conveys the hot air into the cooling chamber, and cooling liquid in the cooling pipe exchanges heat with the hot air to cool the hot air; the second fan cools the box by conveying the cooled air from the bottom of the box to the box again. The hot air is extracted from the top of the box body, and the cold air is input from the bottom of the box body, so that the air flow in the box body can be accelerated, and the effect of better heat dissipation of hardware facilities is achieved. The sealing strip is arranged at the butt joint of the box door and the box body, so that low-temperature gas in the box body can be prevented from leaking. The utility model discloses an inner loop of air in experimental cloud platform box has not only played the radiating effect of cooling down to the hardware facilities, can also prevent that the dust in the outside air from entering into the box, piles up its heat dissipation of hardware facilities surface influence.

The present invention may be further configured in a preferred embodiment as: the mounting panel sets up to the otter board, evenly distributed has a plurality of air vents on the mounting panel.

Through adopting above-mentioned technical scheme, the air vent can allow the cooling air who blows in from the bottom half to pass through for various hardware facilities can contact with cooling air, accelerate hot-air's flow, with the radiating effect of improvement.

The present invention may be further configured in a preferred embodiment as: the bottom end of the box body is communicated with an air chamber, the center of the bottom end of the air chamber is communicated with an air delivery pipe, and the top end of the air chamber is provided with a flow equalizing plate.

Through adopting above-mentioned technical scheme, the gas-supply pipe is inputed cooling air from air chamber bottom center, and cooling air enters into the air chamber, then through the reposition of redundant personnel of flow equalizing plate, can realize letting in cooling air more evenly in the box, can improve radiating effect like this.

The present invention may be further configured in a preferred embodiment as: the extraction pipe is communicated with the center of the top end of the box body, and the top end of the box body is tapered and is provided with a smaller opening at the outer side.

By adopting the technical scheme, hot air in the box body naturally flows upwards, the top end of the box body is arranged to be conical, the diversion effect can be achieved, and the exhaust pipe is communicated with the center of the top end of the box body, so that the hot air in the box body can be discharged more fully, and the hot air is prevented from being accumulated at the top of the box body.

The present invention may be further configured in a preferred embodiment as: a plurality of vertical mounting frames are arranged in the box body, the mounting plates are fixed on the mounting frames, and gaps are reserved between the edges of the mounting plates and the inner wall of the box body; the box body is provided with a plurality of guide plates on two vertical side walls connected with the box door, and the guide plates are arranged in the gap and are arranged in an upward inclined mode at one end close to the mounting plate.

Through adopting above-mentioned technical scheme, cold air can follow the clearance between box lateral wall and the mounting panel and upwards flow, and the guide plate can guide cooling air to the mounting panel direction flow for cooling air and hardware facilities contact can play the radiating effect better like this.

The present invention may be further configured in a preferred embodiment as: and heat insulation layers are also arranged on the outer walls of the cooling chamber and the gas transmission pipe.

Through adopting above-mentioned technical scheme, the setting of insulating layer can play heat retaining effect, prevents that the cooling air in cooling chamber and the gas-supply pipe from taking place heat transfer with outside hot-air.

The present invention may be further configured in a preferred embodiment as: and a liquid receiving tank is also arranged at the bottom of the cooling pipe in the cooling chamber, the bottom end of the liquid receiving tank is communicated with a guide pipe, and the guide pipe is communicated with the outer wall of the cooling chamber.

Through adopting above-mentioned technical scheme, when the hot-air in the box contacted the cooling tube, moisture in the hot-air can take place the liquefaction, can produce the drop on the cooling tube, and the liquid receiving groove can accept the drop, then discharges to the cooling chamber outside through the honeycomb duct.

The present invention may be further configured in a preferred embodiment as: and a buffer cushion is also arranged at the bottom end in the liquid receiving groove.

Through adopting above-mentioned technical scheme, the blotter can set up to materials such as foam-rubber cushion or cotton, and the blotter can prevent that liquid from splashing, prevents that the drippage from colliding with the flume and producing and splashing, and the little drop that splashes falls into the gas-supply pipe easily, then is blown the hardware facilities surface by the second fan, causes the hardware facilities short circuit.

To sum up, the utility model discloses a following at least one useful technological effect:

1. through the arrangement of the air exhaust pipe, the first fan, the cooling chamber, the cooling pipe, the gas pipe and the second fan, the effect of dissipating heat and cooling the interior of the box body can be achieved;

2. through the arrangement of the vent holes, the flow guide plate and the flow equalizing plate, cooling air can be introduced into the box body more uniformly, so that the effect of cooling the interior of the box body is accelerated;

3. through the arrangement of the heat insulation layer, the effect of preventing the cold air in the cooling chamber and the gas transmission pipe from generating heat transfer with the external hot air can be achieved;

4. through the arrangement of the liquid receiving tank, the flow guide pipe and the buffer pad, the effect of better discharging the small water drops liquefied on the cooling pipe to the outside of the cooling chamber can be achieved.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the smart test cloud platform;

FIG. 2 is a schematic diagram of the internal structure of the smart test cloud platform;

fig. 3 is a schematic cross-sectional view of the overall structure of the smart test cloud platform.

In the figure, 1, a box body; 2. an air exhaust pipe; 3. a first fan; 4. a cooling chamber; 41. a cooling tube; 5. a gas delivery pipe; 6. a second fan; 7. an air chamber; 71. a flow equalizing plate; 8. a mounting frame; 9. mounting a plate; 91. a vent hole; 10. a box door; 11. a liquid receiving tank; 12. a flow guide pipe; 13. a cushion pad; 14. a thermal insulation layer; 15. a baffle.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Refer to fig. 1 and fig. 2, do the utility model discloses a experimental cloud platform of wisdom based on switching of multidata source, including box 1, it has chamber door 10 to articulate on 1 side of box, and sealing strip is installed with the butt department of box 1 to chamber door 10. A plurality of mounting brackets 8 are vertically arranged in the box body 1, and a plurality of layers of horizontal mounting plates 9 are arranged on the mounting brackets 8. A plurality of vent holes 91 are uniformly arranged on the mounting plate 9 in a penetrating way, and hardware facilities required by the test cloud platform are also arranged on the mounting plate 9.

Referring to fig. 3, a cooling chamber 4 is installed on an outer wall of the casing 1, a cooling pipe 41 is installed in the cooling chamber 4, the cooling pipe 41 is connected to a cooling device (not shown), and a cooling liquid circulates through the cooling pipe 41. The cooling pipe 41 can be a water cooling pipe, and the cooling liquid in the cooling pipe 41 can also be other condensing agents; the cooling device comprises a power pump for driving the cooling liquid to circularly flow and a condenser for cooling the cooling liquid.

Referring to fig. 3, the center of the top end of the box body 1 is communicated with an exhaust tube 2, and the top end of the box body 1 is arranged to be tapered and has a smaller opening at the outer side. A first fan 3 is further installed at the communication position of the air exhaust pipe 2 and the top end of the box body 1, and one end, far away from the box body 1, of the air exhaust pipe 2 is communicated with the top end of the cooling chamber 4. The bottom end of the box body 1 is communicated with an air chamber 7, the top end of the air chamber 7 is provided with a flow equalizing plate 71, and the center of the bottom end of the air chamber 7 is communicated with an air conveying pipe 5. One end of the gas pipe 5 far away from the air chamber 7 is communicated with the bottom end of the cooling chamber 4. In the working process, various hardware facilities in the box body 1 emit a large amount of heat; the hot air in the cabinet 1 flows toward the top of the cabinet 1, and the first fan 3 draws out and delivers the hot air into the cooling compartment 4. The cooling liquid in the cooling pipe 41 exchanges heat with the hot air to cool the hot air, and then the second fan 6 conveys the cooled air from the bottom of the box body 1 to the box body 1 again to cool the box body 1. The flow equalizing plate 71 may divide the cool air so that the cool air can be more uniformly introduced into the cabinet 1. The outer walls of the cooling chamber 4 and the air conveying pipe 5 are also provided with a heat insulation layer 14, and the heat insulation layer 14 can prevent heat transfer between cooling air in the cooling chamber 4 and the air conveying pipe 5 and external hot air.

Referring to fig. 2, a gap is left between the edge of the mounting plate 9 and the inner wall of the box body 1, a plurality of guide plates 15 are further mounted in the gap on two vertical side walls of the box body 1 connected with the box door 10, and one end of each guide plate 15 close to the mounting plate 9 inclines upwards. The air deflector 15 can guide the cool air flowing through the gap to the direction of the mounting plate 9, so that the cool air contacts with the hardware, which can achieve better heat dissipation effect.

Referring to fig. 3, a liquid receiving tank 11 is further installed at the bottom of the cooling pipe 41 in the cooling chamber 4, a flow guide pipe 12 is communicated with the bottom end of the liquid receiving tank 11, and the flow guide pipe 12 is communicated with the outer wall of the cooling chamber 4. A buffer pad 13 is further arranged at the bottom end inside the liquid receiving tank 11, and the buffer pad 13 can be a spongy cushion or cotton cloth. The liquid receiving tank 11 can receive small water drops dripped from the cooling pipe 41 in a liquefaction manner, the buffer pad 13 can prevent the liquid from splashing, the splashed small water drops can easily fall into the gas conveying pipe 5 and then are blown to the surface of the hardware facility by the second fan 6, and the hardware facility is short-circuited.

The implementation principle of the embodiment is as follows: the hardware required by the test platform is arranged on the mounting plate 9, and a large amount of heat can be emitted from the hardware during the long-term working process of the system. The hot air in the cabinet 1 flows upward, and the first fan 3 draws the hot air out of the cabinet 1 and delivers it to the cooling compartment 4. The hot air is blown to the surface of the cooling pipe 41, and the hot air and the cooling liquid are subjected to heat transfer, so that the temperature of the hot air is reduced. Then the second fan 6 blows the cooled air into the box 1 again from the bottom of the box 1 to cool the box 1. The utility model discloses an air is at the inner loop of test platform box 1, not only can play the effect of cooling down to test platform, can also prevent that the dust from piling up the hardware facilities surface, influences the heat dissipation of hardware facilities.

The embodiment of this specific implementation mode is the preferred embodiment of the present invention, not limit according to this the utility model discloses a protection scope, so: all equivalent changes made according to the structure, shape and principle of the utility model are covered within the protection scope of the utility model.

Claims (8)

1. The utility model provides a experimental cloud platform of wisdom based on switching of multidata source, includes box (1), its characterized in that: a box door (10) is hinged to one side surface of the box body (1), and a sealing strip is further arranged at the abutting position of the box door (10) and the box body (1); a plurality of layers of horizontal mounting plates (9) for mounting hardware facilities are arranged in the box body (1), the top end of the box body (1) is communicated with an air exhaust pipe (2), and a first fan (3) is further arranged in the air exhaust pipe (2) at the communication position of the air exhaust pipe and the box body (1); the bottom end of the box body (1) is communicated with a gas pipe (5), and a second fan (6) is arranged inside one end of the gas pipe (5) communicated with the box body (1); a cooling chamber (4) is further arranged on the outer wall of the box body (1), a cooling pipe (41) is arranged in the cooling chamber (4), the cooling pipe (41) is connected with a heat exchange device, and cooling liquid flows in the cooling pipe (41) in a circulating mode; the top end of the cooling chamber (4) is communicated with the air exhaust pipe (2), and the bottom end of the cooling chamber (4) is communicated with the air delivery pipe (5).

2. The intelligent test cloud platform based on multi-data source switching as claimed in claim 1, wherein: the mounting plate (9) is arranged as a screen plate, and a plurality of vent holes (91) are uniformly distributed on the mounting plate (9).

3. The intelligent test cloud platform based on multi-data source switching as claimed in claim 2, wherein: the bottom end of the box body (1) is communicated with an air chamber (7), the center of the bottom end of the air chamber (7) is communicated with the air conveying pipe (5), and the top end of the air chamber (7) is provided with a flow equalizing plate (71).

4. The intelligent test cloud platform based on multi-data source switching as claimed in claim 3, wherein: the extraction pipe (2) is communicated with the center of the top end of the box body (1), and the top end of the box body (1) is arranged to be conical and the opening on the outer side is smaller.

5. The intelligent test cloud platform based on multi-data source switching as claimed in claim 4, wherein: a plurality of vertical mounting frames (8) are arranged in the box body (1), the mounting plates (9) are fixed on the mounting frames (8), and gaps are reserved between the edges of the mounting plates (9) and the inner wall of the box body (1); a plurality of guide plates (15) are further installed on two vertical side walls connected with the box door (10) on the box body (1), and the guide plates (15) are arranged in the gap and are arranged in an upward inclined mode at one end close to the installation plate (9).

6. The intelligent test cloud platform based on multi-data source switching as claimed in claim 5, wherein: and the outer walls of the cooling chamber (4) and the air conveying pipe (5) are also provided with a heat insulation layer (14).

7. The intelligent test cloud platform based on multi-data source switching as claimed in claim 6, wherein: a liquid receiving tank (11) is further mounted at the bottom of the cooling pipe (41) in the cooling chamber (4), the bottom end of the liquid receiving tank (11) is communicated with a guide pipe (12), and the guide pipe (12) is communicated with the outer wall of the cooling chamber (4).

8. The intelligent test cloud platform based on multi-data source switching according to claim 7, wherein: a buffer pad (13) is also arranged at the bottom end in the liquid receiving tank (11).

Images