CN210630116U - Big data processing platform - Google Patents

Abstract

The utility model is suitable for the technical field of big data processing, and provides a big data processing platform, which comprises a pointing component, a heat exchange component and a condensation component, wherein the pointing component comprises a bottom plate and a cabinet, and is characterized in that a water tank, a circulating pump and a heat exchange plate are arranged to inject heat conduction oil or water into the inner cavity of a heat exchange tube and a heat exchange connecting tube, then condensate water is injected into the water tank, when the circulating pump is started, the heat conduction oil and the water circularly flow in the heat exchange tube and the heat exchange connecting tube, and the heat conduction oil and the water can exchange heat with the condensate water in the inner cavity of the water tank when passing through the heat exchange tube, thereby cooling the heat conduction oil and the water, and exchanging heat with the heat exchange plate when the cooled heat conduction oil and the water flow in the inner cavity of the heat exchange connecting tube, thereby avoiding the phenomenon that, and dust easily enters the server cabinet.

Description

Big data processing platform

Technical Field

The utility model belongs to the technical field of big data calculation, especially, relate to a big data processing platform.

Background

The cloud processing, cloud computing and cloud storage are mainly remote large servers, the servers are provided by operators of corresponding cloud software, the cloud servers are used for processing and computing requirements sent by user cloud software remotely and sending results back to a computer, for example, if the cloud security technology is adopted, an MD5 code is sent to the cloud security server, the cloud server performs comparison with an internal black and white list and then gives the results to the computer of a user, if the problem cannot be identified, the results are sent back to the computer of the user after being processed by the cloud processor, and if the problem cannot be identified, manual work is transferred, and the cloud security technology is a processing mode of the current cloud security technology. Thus, cloud data is relatively to store and save your data in the data server of the operator.

Because cloud processing data computation volume is big for cloud processing platform's server radiating effect will be good, and present big data processing platform's server rack adopts forced air cooling heat dissipation mostly, makes the server rack seted up a large amount of ventilation holes, and not only the radiating effect is relatively poor, and the dust gets into in the server rack easily moreover, thereby causes the problem of damage to the server.

SUMMERY OF THE UTILITY MODEL

The utility model provides a big data processing platform aims at solving the server rack of present big data processing platform and adopts forced air cooling heat dissipation for a large amount of ventilation holes have been seted up to the server rack, and not only the radiating effect is relatively poor, and the dust gets into in the server rack easily moreover, thereby causes the problem of damage to the server.

The utility model discloses a realize like this, a big data processing platform, including pointing out subassembly, heat exchange assembly and condensation subassembly, point out the subassembly and include bottom plate, rack, server placing chamber, cabinet door and hand wheel, the rack with bottom plate fixed connection, the even equidistant division of server placing chamber is in the inner chamber of rack, the cabinet door with the rack rotates to be connected, and even equidistant setting is in the front side between two sets of adjacent server placing chambers, the hand wheel with rack fixed connection;

the heat exchange assembly comprises heat exchange plates, heat exchange fins, U-shaped tubes, heat dissipation windows, isolation nets, fans, sliding blocks, orifice blocking plates and heat exchange connecting tubes, the heat exchange plates are fixedly connected with the cabinet, the heat exchange connecting tubes are uniformly and equidistantly arranged in the inner cavity of the heat exchange plates, the U-shaped tubes are fixedly connected with the heat exchange plates and communicated with two adjacent groups of heat exchange connecting tubes, the heat dissipation windows are arranged in the inner cavity of the rear side wall of the cabinet and the inner cavity of the cabinet door, the isolation nets are fixedly connected with the heat dissipation windows, the fans are fixedly connected with the isolation nets, the sliding blocks are fixedly connected with the cabinet and the cabinet door and are positioned on the left side and the right side of the rear end of the cabinet and the left side and the right side of the front end of the cabinet door, and;

the condensation component comprises a water tank, a supporting plate, heat exchange tubes, a water injection tube, a circulating pump, an electromagnetic valve, a drain tube, a temperature sensor and a single chip microcomputer, the water tank is fixedly connected with the bottom plate and is positioned at the right end of the cabinet, the supporting plate is fixedly connected with the water tank and is positioned at the front side and the rear side of the inner cavity of the water tank, the heat exchange tubes are fixedly connected with the supporting plate and are uniformly and equidistantly arranged between the left group and the right group of the supporting plates, the adjacent two groups of the heat exchange tubes are mutually communicated, the water injection tube and the drain tube are fixedly connected with the water tank, the electromagnetic valve is fixedly connected with the water injection tube and the drain tube, the circulating pump is fixedly connected with the water tank, the output end of the circulating pump is fixedly connected with the tube opening at, the heat exchange connecting pipe is far away from the pipe orifice of the output end of the circulating pump and fixedly connected with the pipe orifice of the other path of the heat exchange pipe, and the temperature sensor is fixedly connected with the water tank.

The utility model discloses it is preferred still to provide, it still includes the universal wheel to point out the subassembly the universal wheel with bottom plate fixed connection.

The utility model discloses still provide preferred, point out that the subassembly is good including supporting screw, supporting legs and hand wheel, supporting screw with the bottom plate rotates to be connected, and run through in the four corners of bottom plate extends to the bottom of bottom plate, the supporting legs with supporting screw rotates to be connected and is located the bottom of bottom plate, the hand wheel with supporting screw fixed connection.

The utility model discloses it is preferred still to provide, the heat transfer board is corrugated structure.

The utility model discloses still provide preferred, heat exchange assembly still includes heat transfer fin, heat transfer fin even equidistant set up in the heat transfer board is kept away from one side of indoor lateral wall is placed to the server.

Compared with the prior art, the beneficial effects of the utility model are that: the utility model discloses a big data processing platform, through setting up the water tank, circulating pump and heat transfer plate, make the inner chamber of heat exchange tube and heat exchange connecting pipe inject heat-conducting oil or water, then pour into the comdenstion water into the water tank, when starting up the circulating pump, the heat-conducting oil and the water in the inner chamber of heat exchange tube and heat exchange connecting pipe circulate and flow in heat exchange tube and heat exchange connecting pipe, heat-conducting oil and water can exchange heat with the comdenstion water in the inner chamber of water tank when passing through the heat exchange tube, thereby heat-conducting oil and water cooling, when the heat-conducting oil and water after cooling flow in the inner chamber of heat exchange connecting pipe, can exchange heat with the heat transfer plate, thereby cool down the inner chamber of server placing chamber, thereby avoid the server rack of the present big data processing platform mostly adopting air cooling heat dissipation, make the server rack, thereby causing a problem of damage to the server.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a rear view of the structure of the present invention;

FIG. 3 is a top view of the present invention showing the construction of the modules and heat exchange modules;

FIG. 4 is a schematic diagram of the heat exchange plate structure of the present invention;

FIG. 5 is a schematic diagram of the structure of the supporting plate of the present invention;

fig. 6 is a schematic block diagram of the present invention.

In the figure: 1-point component, 11-bottom plate, 12-universal wheel, 13-cabinet, 14-server placing chamber, 15-cabinet door, 16-supporting screw, 17-supporting foot, 18-hand wheel, 19-big data processing server, 2-heat exchange component, 21-heat exchange plate, 22-heat exchange fin, 23-U-shaped pipe, 24-heat dissipation window, 25-isolation net, 26-fan, 27-slide block, 28-orifice blocking plate, 29-heat exchange connecting pipe, 3-condensation component, 31-water tank, 32-supporting plate, 33-heat exchange pipe, 34-water injection pipe, 35-circulating pump, 36-electromagnetic valve, 37-water discharge pipe, 38-temperature sensor and 39-single chip microcomputer.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Referring to fig. 1-6, the utility model provides a big data processing platform, including pointing out subassembly 1, heat exchange module 2 and condensation subassembly 3, point out subassembly 1 including bottom plate 11, cabinet 13, server placing chamber 14, cabinet door 15 and hand wheel 18, cabinet 13 and bottom plate 11 fixed connection, and be located the top of bottom plate 11, server placing chamber 14 is even equidistant to be seted up in the inner chamber of cabinet 13, cabinet door 15 and cabinet 13 rotate to be connected, and even equidistant setting is in the front side between two sets of adjacent server placing chambers 14, hand wheel 18 and cabinet 13 fixed connection, and be located the inner chamber of server placing chamber 14;

the heat exchange component 2 comprises a heat exchange plate 21, heat exchange fins 22, U-shaped pipes 23, a heat dissipation window 24, an isolation net 25, a fan 26, a sliding block 27, a pore blocking plate 28 and heat exchange connecting pipes 29, wherein the heat exchange plate 21 is fixedly connected with the cabinet 13 and is positioned on the left side wall, the right side wall and the upper wall of the inner cavity of the server placing chamber 14, the heat exchange connecting pipes 29 are uniformly and equidistantly provided with inner cavities connected with the heat exchange plate 21, the U-shaped pipes 23 are fixedly connected with the heat exchange plate 21 and are communicated with two adjacent groups of heat exchange connecting pipes 29, the heat dissipation window 24 is arranged on the inner cavity of the rear side wall of the cabinet 13 and the inner cavity of the cabinet door 15, the isolation net 25 is fixedly connected with the heat dissipation window 24 and is positioned in the inner cavity of the heat dissipation window 24, the fan 26 is fixedly connected with the isolation net 25 and is positioned in the inner cavity of the isolation net, the orifice blocking plate 28 is connected with the slide blocks 27 in a sliding manner and is positioned between the left slide block 27 and the right slide block 27;

the condensing assembly 3 comprises a water tank 31, supporting plates 32, heat exchange pipes 33, water injection pipes 34, a circulating pump 35, an electromagnetic valve 36, a drain pipe 37, a temperature sensor 38 and a single chip microcomputer 39, wherein the water tank 31 is fixedly connected with the bottom plate 11 and is positioned at the right end of the cabinet 13, the supporting plates 32 are fixedly connected with the water tank 31 and are positioned at the front side and the rear side of an inner cavity of the water tank 31, the heat exchange pipes 33 are fixedly connected with the supporting plates 32 and are uniformly arranged between the left supporting plate 32 and the right supporting plate 32 at equal intervals, the adjacent two groups of heat exchange pipes 33 are communicated with each other, the water injection pipes 34 and the drain pipe 37 are both fixedly connected with the water tank 31 and are positioned at the upper end and the lower end of the right side wall of the water tank 31, the electromagnetic valve 36 is fixedly connected with the water injection pipes 34 and the drain pipe 37 and is respectively positioned at one side of the, a pipe orifice at one end of the heat exchange pipe 33 is fixedly connected with an input end of the circulating pump 35, a pipe orifice of the heat exchange connecting pipe 29 far away from an output end of the circulating pump 35 is fixedly connected with a pipe orifice of the other path of the heat exchange pipe 33, the temperature sensor 38 is fixedly connected with the water tank 31 and is positioned in an inner cavity of the water tank 31, and the single chip microcomputer 39 is electrically connected with the electromagnetic valve 36 and the temperature sensor 38.

In this embodiment, by providing the water tank 31, the circulating pump 35 and the heat exchange plate 21, heat conducting oil or water is injected into the inner cavities of the heat exchange tube 33 and the heat exchange connection tube 29, and then condensed water is injected into the water tank 31, so that when the circulating pump 35 is started, the heat conducting oil and water in the inner cavities of the heat exchange tube 33 and the heat exchange connection tube 29 circularly flow in the heat exchange tube 33 and the heat exchange connection tube 29, and the heat conducting oil and water can exchange heat with the condensed water in the inner cavity of the water tank 31 when passing through the heat exchange tube 33, so that the heat conducting oil and water are cooled, and when the cooled heat conducting oil and water flow in the inner cavity of the heat exchange connection tube 29, the heat conducting oil and water can exchange heat with the heat exchange plate 21, thereby cooling the inner cavity of the server placing chamber 14, thereby avoiding that most of the existing server cabinet of, thereby cause the damage to the server, simultaneously through setting up fan 26 and hindering orifice plate 28 for can drawing out hindering orifice plate 28 from controlling between two sets of sliders 27, then switch on the power with fan 26, make fan 26 circular telegram work, thereby utilize fan 26 to dispel the heat to the inner chamber of server placing chamber 14, increased the radiating mode to the inner chamber of server placing chamber 14.

Further, the pointing module 1 further includes a universal wheel 12, wherein the universal wheel 12 is fixedly connected with the bottom plate 11 and is located at four corners of the bottom end of the bottom plate 11.

In this embodiment, the universal wheels 12 can facilitate the movement of the bottom plate 11, thereby avoiding the inconvenience in moving the cabinet 13.

Further, it is noted that the assembly 1 preferably includes a support screw 16, a support leg 17 and a hand wheel 18, the support screw 16 is rotatably connected to the bottom plate 11 and penetrates four corners of the bottom plate 11 and extends to the bottom end of the bottom plate 11, the support leg 17 is rotatably connected to the support screw 16 and is located at the bottom end of the bottom plate 11, and the hand wheel 18 is fixedly connected to the support screw 16 and is located at the top end of the support screw 16.

In this embodiment, the user can rotate the hand wheel 18 at the same time, so that the hand wheel 18 drives the support screw 16 and the support leg 17 to move downward, so that the support leg 17 contacts with the ground, thereby supporting the bottom plate 11.

Further, the heat exchange plates 21 are corrugated.

In the present embodiment, the corrugated heat exchange plate 21 effectively increases the surface area of the heat exchange plate 21, and effectively improves the heat exchange effect between the heat exchange plate 21 and the air in the inner cavity of the server placing chamber 14.

Further, the heat exchange assembly 2 further comprises heat exchange fins 22, and the heat exchange fins 22 are uniformly and equidistantly arranged on one side of the heat exchange plate 21, which is far away from the inner side wall of the server placing chamber 14.

In the present embodiment, the surface area of the heat exchange plate 21 is further increased by providing the heat exchange fins 22, so that the heat exchange effect between the heat exchange plate 21 and the air in the inner cavity of the server placing chamber 14 is further improved.

The utility model discloses a theory of operation and use flow: after the utility model is installed, the condensed water is injected into the inner cavity of the water tank 31, the liquid level is higher than the top end of the support plate 32, then the heat transfer oil or water is injected into the inner cavities of the heat exchange tube 33 and the heat exchange connecting tube 29, then the circulating pump 35 is started, so that the heat transfer oil and the water circularly flow in the heat exchange tube 33 and the heat exchange connecting tube 29, the heat transfer oil and the water can exchange heat with the condensed water in the inner cavity of the water tank 31 when passing through the heat exchange tube 33, thereby cooling the heat transfer oil and the water, when the cooled heat transfer oil and the cooled water flow in the inner cavity of the heat exchange connecting tube 29, the heat transfer oil and the heat exchange plate 21 can exchange heat, thereby cooling the inner cavity of the server placing chamber 14, so as to achieve the purpose of cooling the hand wheel 18, thereby avoiding the server cabinet of, moreover, dust is easy to enter the server cabinet, thereby causing damage to the server, the temperature of the condensed water is continuously raised after long-time heat exchange, meanwhile, the temperature sensor 38 can detect the temperature of the condensed water in the inner cavity of the water tank 31 in real time, and when the temperature is too high, the singlechip 39 controls the electromagnetic valve 36 at the drain pipe 37 to open, thereby discharging the condensed water with higher temperature in the inner cavity of the water tank 31, then the single chip microcomputer 39 controls the electromagnetic valve 36 at the water injection pipe 34 to start, so as to inject the condensed water with lower temperature, when no condensed water exists around the platform, the orifice blocking plate 28 can be drawn out from between the left and right groups of slide blocks 27, then, the fan 26 is powered on, so that the fan 26 is powered on to work, the fan 26 is utilized to dissipate heat of the inner cavity of the server placing chamber 14, a heat dissipation mode of the inner cavity of the server placing chamber 14 is increased, and the problem that the inner cavity of the server placing chamber 14 cannot dissipate heat normally due to the fact that no condensed water exists is solved.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modifications, equivalents, improvements and the like made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims (5)

1. A big data processing platform, comprising: the heat exchanger comprises an indicating component (1), a heat exchange component (2) and a condensing component (3), wherein the indicating component (1) comprises a bottom plate (11), a cabinet (13), server placing chambers (14), a cabinet door (15) and hand wheels (18), the cabinet (13) is fixedly connected with the bottom plate (11), the server placing chambers (14) are uniformly and equidistantly arranged in an inner cavity of the cabinet (13), the cabinet doors (15) are rotatably connected with the cabinet (13), the cabinet doors are uniformly and equidistantly arranged on the front side between two adjacent groups of server placing chambers (14), and the hand wheels (18) are fixedly connected with the cabinet (13);

the heat exchange assembly (2) comprises heat exchange plates (21), heat exchange fins (22), U-shaped pipes (23), heat dissipation windows (24), an isolation net (25), fans (26), sliders (27), hole blocking plates (28) and heat exchange connecting pipes (29), the heat exchange plates (21) are fixedly connected with the cabinet (13) and are positioned on the left side wall, the right side wall and the upper wall of an inner cavity of the server placing chamber (14), the heat exchange connecting pipes (29) are uniformly arranged in the inner cavity of the heat exchange plates (21) at equal intervals, the U-shaped pipes (23) are fixedly connected with the heat exchange plates (21) and are communicated with two adjacent groups of heat exchange connecting pipes (29), the heat dissipation windows (24) are arranged in an inner cavity of the rear side wall of the cabinet (13) and an inner cavity of the cabinet door (15), the isolation net (25) is fixedly connected with the heat dissipation windows (24) and is positioned in an inner cavity of the heat dissipation windows (24), and the fans (26), the sliding blocks (27) are fixedly connected with the cabinet (13) and the cabinet door (15), and are positioned on the left side and the right side of the rear end of the cabinet (13) and the left side and the right side of the front end of the cabinet door (15), and the hole blocking plates (28) are slidably connected with the sliding blocks (27);

the condensation component (3) comprises a water tank (31), a support plate (32), heat exchange tubes (33), water injection tubes (34), a circulating pump (35), an electromagnetic valve (36), a drain tube (37), a temperature sensor (38) and a single chip microcomputer (39), the water tank (31) is fixedly connected with the bottom plate (11), the support plate (32) is fixedly connected with the water tank (31), the heat exchange tubes (33) are fixedly connected with the support plate (32) and are uniformly and equidistantly arranged between the left and right two groups of support plates (32), the adjacent two groups of heat exchange tubes (33) are mutually communicated, the water injection tubes (34) and the drain tube (37) are fixedly connected with the water tank (31), the electromagnetic valve (36) is fixedly connected with the water injection tubes (34) and the drain tube (37), the circulating pump (35) is fixedly connected with the water tank (31), the output end of the circulating pump (35) is fixedly connected with the tube opening at one end of, the one end mouth of pipe of heat exchange tube (33) with the input fixed connection of circulating pump (35), the mouth of pipe of the output of circulating pump (35) and another way mouth of pipe fixed connection of heat exchange tube (33) are kept away from in heat transfer connecting pipe (29), temperature sensor (38) and water tank (31) fixed connection.

2. The big data processing platform of claim 1, wherein: the indicating assembly (1) further comprises a universal wheel (12), and the universal wheel (12) is fixedly connected with the bottom plate (11).

3. The big data processing platform of claim 1, wherein: indicate subassembly (1) still includes supporting screw (16), supporting legs (17) and hand wheel (18), supporting screw (16) rotate with bottom plate (11) and are connected, supporting legs (17) rotate with supporting screw (16) and are connected and are located the bottom of bottom plate (11), hand wheel (18) and supporting screw (16) fixed connection.

4. The big data processing platform of claim 1, wherein: the heat exchange plate (21) is of a corrugated structure.

5. The big data processing platform of claim 1, wherein: the heat exchange assembly (2) further comprises heat exchange fins (22), and the heat exchange fins (22) are uniformly arranged on one side, away from the inner side wall of the server placing chamber (14), of the heat exchange plate (21) at equal intervals.

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