CN220755303U - Efficient heat dissipation data server structure - Google Patents

Abstract

The utility model discloses a data server structure with high-efficiency heat dissipation, which comprises a box body and a flow guiding mechanism; the box body comprises: the front end of the box body is hinged with a box door through a hinge, the left end and the right end of the inside of the box body are respectively provided with a vertical partition board, a transverse hollow partition board is respectively arranged between the two vertical partition boards and is respectively communicated with a communication hole on the surface of the vertical partition board, the upper surface of the transverse hollow partition board is provided with a data storage device, the lower end of the bottom wall of the box body is provided with a PLC (programmable logic controller), the input end of the PLC is electrically connected with an external power supply, the high-efficiency heat dissipation data server structure prevents dust from accumulating on the surface of an electric appliance part of the data server, the heat exchange time between gas and a heating element of the data server can be controlled according to the height of the internal temperature of the data server, the heat exchange between the gas and the heating element of the data server is more sufficient, and the heat dissipation of the data server is more efficient.

Description

Efficient heat dissipation data server structure

Technical Field

The utility model relates to the technical field of data servers, in particular to a data server structure with efficient heat dissipation.

Background

The data server is a special server for running the database system, and has the functions of providing hardware support and guarantee for high-performance running of the database system, and is composed of one or more computers running in a local area network and database management system software, and provides data services for client application programs, wherein the services comprise: aspects of querying, updating, transaction management, indexing, caching, query optimization, security, multi-user access control, and the like; in the prior art, because the data server can give off heat in the operation process, so need at data server internally mounted radiator unit, the heat dissipation is carried out to data server inside, the heat dissipation mode of commonly used is mostly forced air cooling heat dissipation, utilize the flow of air, with the inside heat outside of data server, but in forced air cooling radiating process, outside dust also gets into data server inside easily, the time is piled up at data server electrical apparatus part surface easily, the effect of easily introducing air and heat dissipation reduces, and under the different circumstances of data server inside temperature, the speed of heat transfer also differs between air and the data server heat-generating body, when the temperature is lower, the heat exchange between gas and the data server heat-generating body is insufficient easily, the radiating efficiency is lower.

Disclosure of Invention

The utility model aims to overcome the existing defects, and provides a data server structure with high-efficiency heat dissipation, which can prevent dust from accumulating on the surface of an electric part of a data server, so that heat exchange between gas and a heating element of the data server is more sufficient, the heat dissipation of the data server is more efficient, and the problems in the background art can be effectively solved.

In order to achieve the above purpose, the present utility model provides the following technical solutions: a data server structure with high-efficiency heat dissipation comprises a box body and a flow guiding mechanism;

the box body comprises: the front end of the box body is hinged with a box door through a hinge, the left end and the right end of the inside of the box body are respectively provided with a vertical partition board, a transverse hollow partition board is respectively arranged between the two vertical partition boards, the transverse hollow partition boards are respectively communicated with communication holes on the surfaces of the vertical partition boards, the upper surfaces of the transverse hollow partition boards are respectively provided with a data storage device, the lower end of the bottom wall of the box body is provided with a PLC (programmable logic controller), the input end of the PLC is electrically connected with an external power supply, the data storage devices are respectively and electrically connected with the PLC in a bidirectional manner, the right side surface of the box body is respectively provided with a heat dissipation hole, and the mounting holes on the left side surface of the box body are respectively provided with an air outlet pipe;

the flow guiding mechanism comprises: the heat dissipation device is characterized in that the heat dissipation device is arranged in the transverse hollow partition plates respectively, the heat dissipation is carried out on the inside of the data server while the contact of external dust and electric parts is avoided, the dust is prevented from accumulating on the surface of the electric parts of the data server, the heat dissipation effect of the data server is improved, the heat exchange time between gas and a heating body of the data server can be controlled according to the temperature inside the data server, the heat exchange between the gas and the heating body of the data server is more sufficient, and the heat dissipation of the data server is more efficient.

Further, the flow guiding mechanism comprises first heat conducting plates, the first heat conducting plates are respectively connected between the upper ends of the front inner wall and the rear inner wall of the transverse hollow partition plate through rotating shafts in a rotating mode, the length of each first heat conducting plate is smaller than the distance between the upper inner wall and the lower inner wall of the transverse hollow partition plate, and ventilation of air inside the transverse hollow partition plate is blocked.

Further, the flow guiding mechanism further comprises a second heat conducting plate and air holes, the second heat conducting plate is respectively connected between the upper ends of the front inner wall and the rear inner wall of the transverse hollow partition plate through a second rotating shaft, the air holes are formed in the upper ends of the second heat conducting plates, the second heat conducting plates and the first heat conducting plates in the same transverse hollow partition plate are distributed at intervals from left to right, the length of the second heat conducting plates is larger than the distance between the upper inner wall and the lower inner wall of the transverse hollow partition plate, and ventilation of air inside the transverse hollow partition plate is further blocked.

Further, guiding mechanism still includes steering column, guiding groove, spout and slide, the spout sets up respectively in the front end of horizontal hollow baffle, and the inside of spout is all vertical sliding connection has the slide, and the rear side inner wall of spout is equipped with the guiding groove respectively, and the steering column sets up respectively in the lower extreme of second heat-conducting plate and first heat-conducting plate, and the front end of steering column passes the inside of guiding groove respectively and with slide cooperation installation, conveniently rotates second heat-conducting plate and first heat-conducting plate.

Further, the flow guiding mechanism further comprises a screw and a motor, the motor is arranged on the upper surface of the box body respectively, the lower end of an output shaft of the motor is provided with the screw, the screw is located in a rotating hole of the integral front end formed by the vertical partition plate and the transverse hollow partition plate respectively, threaded pipes at the left end and the right end of the sliding plate are connected with the adjacent screw in a threaded mode respectively, the input end of the motor is electrically connected to the output end of the PLC, and power is provided for rotation of the second heat conducting plate and the first heat conducting plate.

Further, temperature sensors are respectively arranged on the inner walls of the rear sides of the box bodies, the output ends of the temperature sensors are electrically connected to the input ends of the PLC, and the temperature inside the data server is detected.

Further, the inside of play tuber pipe all is equipped with the electric fan, and the input of electric fan is connected in the output of PLC controller, provides power for the circulation of air.

Compared with the prior art, the utility model has the beneficial effects that: the high-efficiency heat dissipation data server structure has the following advantages:

1. when the device is used, the data storage device is used for providing storage service for data, the data are conveniently called, in the use process, the electric fan is started through the PLC, external air enters the transverse hollow partition plate through the heat dissipation holes and the communication holes on the surface of the vertical partition plate, the transverse hollow partition plate made of aluminum alloy materials is used for conducting heat dissipated in the data storage device reading and writing process to the air flowing in the transverse hollow partition plate, finally the air is discharged from the air outlet pipe, external dust is prevented from being contacted with the electric appliance part, heat dissipation is carried out inside the data server, dust is prevented from accumulating on the surface of the electric appliance part of the data server, and the heat dissipation effect of the data server is improved.

2. When the internal temperature of the data server is lower, the heat transfer speed is slower, the motor is started, the sliding plate is enabled to move, the second heat conducting plate and the first heat conducting plate are enabled to be in an inclined state, the flow of air is blocked, the flow speed of the air in the transverse hollow partition plate is reduced, meanwhile, the heat conducting area is increased, more heat can be emitted by the air flow with the same volume, when the internal temperature of the data server is higher, the heat transfer speed is fast because the temperature difference is larger, the sliding plate is utilized to rotate the second heat conducting plate and the first heat conducting plate to be in a horizontal state, the heat exchange speed of the air in the transverse hollow partition plate is accelerated, the heat exchange time between the air and the heating element of the data server can be controlled according to the internal temperature of the data server, the heat exchange between the air and the heating element of the data server is more sufficient, and the heat dissipation of the data server is more efficient.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic view of the structure of the transverse hollow partition board of the present utility model;

FIG. 3 is a schematic structural view of a cross-section of a transverse hollow partition wall of the present utility model;

fig. 4 is a schematic cross-sectional front end elevational view of the transverse hollow partition wall of the present utility model.

In the figure: the device comprises a box body 1, a box door 2, a transverse hollow partition plate 3, a vertical partition plate 4, a data storage device 5, a PLC controller 6, an air outlet pipe 7, a heat dissipation hole 8, a flow guiding mechanism 9, a first heat conducting plate 91, a rotating column 92, a second heat conducting plate 93, a wind hole 94, a guiding groove 95, a sliding groove 96, a sliding plate 97, a screw rod 98, a motor 99, a temperature sensor 10 and an electric fan 11.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-4, the present embodiment provides a technical solution: a data server structure with high-efficiency heat dissipation comprises a box body 1 and a flow guiding mechanism 9;

case 1: the front end of the box body is hinged with a box door 2 through a hinge, the opening of the front end of the box body 1 is sealed, the left end and the right end of the inside of the box body 1 are respectively provided with a vertical partition board 4, a transverse hollow partition board 3 is respectively arranged between the two vertical partition boards 4, the transverse hollow partition boards 3 are respectively communicated with communication holes on the surfaces of the vertical partition boards 4, the space inside the box body 1 is separated, meanwhile, the flow track of radiating air is guided, the radiating effect is improved, a data storage 5 is arranged on the upper surface of the transverse hollow partition board 3, the front end of the data storage 5 is connected with the transverse hollow partition board 3 through bolts, the data are provided with storage service, the data are conveniently read and written, the lower end of the bottom wall of the box body 1 is provided with a PLC 6, the input end of the PLC 6 is electrically connected with an external power supply, the starting and stopping of the whole device are controlled, the data storage 5 is electrically connected with the PLC 6 in a bidirectional way, the right side surface of the box body 1 is respectively provided with a heat dissipation hole 8, the mounting holes on the left side surface of the box body 1 are respectively provided with an air outlet pipe 7, external air enters the box body 1 through the heat dissipation holes 8 and enters the transverse hollow partition 3 through the communication holes on the surface of the vertical partition 4, heat emitted in the process of reading and writing data in the data storage 5 by the transverse hollow partition 3 made of aluminum alloy materials is conducted into the air flowing in the transverse hollow partition 3, finally the air is discharged from the air outlet pipes 7, the heat dissipation is carried out in the data server while the contact of external dust and electric appliance components is avoided, the rear side inner wall of the box body 1 is respectively provided with a temperature sensor 10, the output end of the temperature sensor 10 is electrically connected with the input end of the PLC 6, the temperature in the space where the data storage 5 is located is detected, the inside of the air outlet pipe 7 is provided with an electric fan 11, and the input end of the electric fan 11 is electrically connected with the output end of the PLC 6 to provide power for air circulation;

the flow guiding mechanism 9: the air guide mechanism 9 is respectively arranged in the transverse hollow partition plate 3, the air guide mechanism 9 comprises a first heat-conducting plate 91, the first heat-conducting plate 91 is respectively connected between the upper ends of the front inner wall and the rear inner wall of the transverse hollow partition plate 3 through rotation of a rotating shaft, the length of the first heat-conducting plate 91 is smaller than the distance between the upper inner wall and the lower inner wall of the transverse hollow partition plate 3, the air guide mechanism 9 also comprises a second heat-conducting plate 93 and an air hole 94, the second heat-conducting plate 93 is respectively connected between the upper ends of the front inner wall and the rear inner wall of the transverse hollow partition plate 3 through rotation of a rotating shaft II, the upper ends of the second heat-conducting plates 93 are respectively provided with the air hole 94, the second heat-conducting plates 93 and the first heat-conducting plates 91 in the same transverse hollow partition plate 3 are distributed at intervals from left to right, the length of the second heat-conducting plates 93 is larger than the distance between the upper inner wall and the lower inner wall of the transverse hollow partition plate 3, the air guide mechanism 9 also comprises a rotating column 92, a guide groove 95, a sliding groove 96 and a sliding plate 97 are respectively arranged at the front end of the transverse hollow partition plate 3, the inside of the sliding groove 96 is vertically and slidingly connected with a sliding plate 97, the inner wall of the rear side of the sliding groove 96 is respectively provided with a guide groove 95, a rotating column 92 is respectively arranged at the lower ends of the second heat-conducting plate 93 and the first heat-conducting plate 91, the front end of the rotating column 92 respectively penetrates through the inside of the guide groove 95 and is matched with the sliding plate 97 for installation, the flow guiding mechanism 9 also comprises a screw rod 98 and a motor 99, the motor 99 is respectively arranged on the upper surface of the box body 1, the lower end of an output shaft of the motor 99 is respectively provided with a screw rod 98, the screw rods 98 are respectively positioned in rotating holes of the integral front end formed by the vertical partition plate 4 and the transverse hollow partition plate 3, threaded pipes at the left end and the right end of the sliding plate 97 are respectively connected with the adjacent screw rods 98 in a threaded manner, the input end of the motor 99 is electrically connected with the output end of the PLC 6, when the temperature inside the data server is lower, the motor 99 is started, the output shaft of the motor 99 drives the screw rod 98 to rotate, through two screw rods 98 and a slide 97 threaded connection, make slide 97 downwardly moving, this moment under the gravity effect of second heat-conducting plate 93, first heat-conducting plate 91 and revolving post 92 self, make second heat-conducting plate 93 anticlockwise rotate, first heat-conducting plate 91 clockwise turn, because the length of first heat-conducting plate 91 is less than the interval of horizontal hollow baffle 3 upper and lower inner wall, the length of second heat-conducting plate 93 is greater than horizontal hollow baffle 3 upper and lower inner wall's interval, so there is the clearance between the diapire of first heat-conducting plate 91 and horizontal hollow baffle 3, the air circulates from the downside of first heat-conducting plate 91, and the lower extreme of second heat-conducting plate 93 contacts to the diapire of hollow baffle 3, make the air circulate from the wind hole 94, produce the blocking to the flow of air, reduce the flow rate of inside air of horizontal hollow baffle 3, increase the heat conduction area simultaneously, make the air flow of same volume can dispel more heat, when the inside temperature is higher in the same way, because the difference in temperature is higher, the transfer rate of heat is fast, utilize the upward movement of 97 makes second heat-conducting plate 91 and first heat-conducting plate and the air flow to the horizontal air flow to the hollow baffle 3, the effect of the heat dissipation is not equal, the air flow is higher, when the air flow is not equal to the air flow to the horizontal flow is produced, and the air flow is more than the air flow to the air flow is cooled.

The working principle of the data server structure with high-efficiency heat dissipation provided by the utility model is as follows: when the air conditioner is used, the PLC 6 is connected with external data transmission equipment, the data storage device 5 is used for providing storage service for data, the data can be conveniently called, in the using process, the electric fan 11 is started by the PLC 6, so that air flows, the outside air enters the inside of the box body 1 through the heat dissipation holes 8 and enters the inside of the transverse hollow partition plate 3 through the communication holes on the surface of the vertical partition plate 4, the heat dissipated in the process of reading and writing the data by the data storage device 5 is conducted into the air flowing inside the transverse hollow partition plate 3 by the transverse hollow partition plate 3 made of aluminum alloy materials, and finally the air is discharged from the air outlet pipe 7, the external dust is prevented from contacting with electrical parts, the heat dissipation is carried out inside the data server, meanwhile, the temperature in the space where the data storage device 5 is located is detected by the temperature sensor 10, when the temperature inside the data server is lower, the heat transfer speed is slower, the motor 99 is started, the output shaft of the motor 99 drives the screw rod 98 to rotate, the two screw rods 98 are in threaded connection with one slide plate 97 to enable the slide plate 97 to move downwards, at the moment, the second heat conducting plate 93 rotates anticlockwise under the action of the gravity of the second heat conducting plate 93, the first heat conducting plate 91 and the rotating column 92, the first heat conducting plate 91 rotates clockwise, because the length of the first heat conducting plate 91 is smaller than the distance between the upper inner wall and the lower inner wall of the transverse hollow partition plate 3, the length of the second heat conducting plate 93 is larger than the distance between the upper inner wall and the lower inner wall of the transverse hollow partition plate 3, a gap exists between the first heat conducting plate 91 and the bottom wall of the transverse hollow partition plate 3, air flows from the lower side of the first heat conducting plate 91, the lower end of the second heat conducting plate 93 contacts with the bottom wall of the hollow partition plate 3 to enable air to flow from the air hole 94 to block the air flow, the flow speed of the air in the transverse hollow partition plate 3 is reduced, the heat conduction area is increased, more heat can be emitted by the air flow with the same volume, and similarly, when the temperature in the data server is higher, the heat transfer speed is high because the temperature difference is larger, the second heat conduction plate 93 and the first heat conduction plate 91 are both rotated to a horizontal state by utilizing the upward movement of the sliding plate 97, the air flow can not be blocked, the air circulation speed in the transverse hollow partition plate 3 is accelerated, and the heat dissipation effect is higher.

It should be noted that, in the above embodiment, the PLC controller 6 may be a TPC8-8TD PLC controller, the data storage 5, the motor 99, the temperature sensor 10 and the electric fan 11 may be freely configured according to the actual application scenario, the data storage 5 may be a VSC7427XJG-02 type storage, the motor 99 may be a 3M57-42A type stepper motor, the temperature sensor 10 may be a 10TP583T type temperature sensor, the electric fan 11 may be a 12020 type radiator fan, and the PLC controller 6 controls the data storage 5, the motor 99, the temperature sensor 10 and the electric fan 11 to operate by methods commonly used in the prior art.

The foregoing is only illustrative of the present utility model and is not to be construed as limiting the scope of the utility model, and all equivalent structures or equivalent flow modifications which may be made by the teachings of the present utility model and the accompanying drawings or which may be directly or indirectly employed in other related art are within the scope of the utility model.

Claims (7)

1. The utility model provides a high-efficient radiating data server structure which characterized in that: comprises a box body (1) and a flow guiding mechanism (9);

box (1): the front end of the box body is hinged with a box door (2) through a hinge, the left end and the right end of the inside of the box body (1) are respectively provided with a vertical partition board (4), a transverse hollow partition board (3) is respectively arranged between the two vertical partition boards (4), the transverse hollow partition boards (3) are respectively communicated with communication holes on the surfaces of the vertical partition boards (4), the upper surfaces of the transverse hollow partition boards (3) are respectively provided with a data storage device (5), the lower end of the bottom wall of the box body (1) is provided with a PLC (programmable logic controller) 6), the input end of the PLC (6) is electrically connected with an external power supply, the data storage devices (5) are respectively and electrically connected with the PLC (6) in a bidirectional manner, the right side surface of the box body (1) is respectively provided with a heat dissipation hole (8), and the mounting holes on the left side surface of the box body (1) are respectively provided with an air outlet pipe (7);

flow guiding mechanism (9): are respectively arranged in the transverse hollow partition boards (3).

2. The high efficiency heat dissipating data server structure of claim 1, wherein: the flow guide mechanism (9) comprises first heat conduction plates (91), the first heat conduction plates (91) are respectively connected between the upper ends of the front inner wall and the rear inner wall of the transverse hollow partition plate (3) through rotating shafts in a rotating mode, and the length of each first heat conduction plate (91) is smaller than the distance between the upper inner wall and the lower inner wall of the transverse hollow partition plate (3).

3. The high efficiency heat dissipating data server structure of claim 2, wherein: the flow guide mechanism (9) further comprises a second heat-conducting plate (93) and air holes (94), the second heat-conducting plate (93) is respectively connected between the upper ends of the front inner wall and the rear inner wall of the transverse hollow partition plate (3) through a second rotating shaft, the air holes (94) are formed in the upper ends of the second heat-conducting plate (93), the second heat-conducting plate (93) and the first heat-conducting plate (91) in the same transverse hollow partition plate (3) are distributed at intervals from left to right, and the length of the second heat-conducting plate (93) is larger than the distance between the upper inner wall and the lower inner wall of the transverse hollow partition plate (3).

4. A high efficiency heat dissipating data server structure in accordance with claim 3, wherein: the guide mechanism (9) further comprises a rotating column (92), guide grooves (95), sliding grooves (96) and sliding plates (97), wherein the sliding grooves (96) are respectively formed in the front ends of the transverse hollow partition plates (3), the sliding plates (97) are vertically and slidingly connected in the sliding grooves (96), the guide grooves (95) are respectively formed in the inner walls of the rear sides of the sliding grooves (96), the rotating column (92) is respectively arranged at the lower ends of the second heat-conducting plates (93) and the first heat-conducting plates (91), and the front ends of the rotating column (92) respectively penetrate through the inner parts of the guide grooves (95) and are matched with the sliding plates (97).

5. The high efficiency heat dissipating data server structure of claim 4, wherein: the guide mechanism (9) further comprises a screw rod (98) and a motor (99), the motor (99) is respectively arranged on the upper surface of the box body (1), the lower end of an output shaft of the motor (99) is provided with the screw rod (98), the screw rod (98) is respectively positioned in a rotating hole of the integral front end formed by the vertical partition plate (4) and the transverse hollow partition plate (3), threaded pipes at the left end and the right end of the sliding plate (97) are respectively in threaded connection with the adjacent screw rods (98), and the input end of the motor (99) is electrically connected with the output end of the PLC (6).

6. The high efficiency heat dissipating data server structure of claim 1, wherein: the rear side inner wall of the box body (1) is respectively provided with a temperature sensor (10), and the output end of the temperature sensor (10) is electrically connected with the input end of the PLC (6).

7. The high efficiency heat dissipating data server structure of claim 1, wherein: the inside of play tuber pipe (7) all is equipped with electric fan (11), and the input of electric fan (11) is connected in the output of PLC controller (6) electricity.