CN214316052U - Air guide type waste heat utilization structure - Google Patents

Abstract

The utility model discloses a wind conduction formula waste heat utilization structure, include the cooler bin and set up the condensation structure on the cooler bin, the condensation structure includes the condenser pipe, condenser pipe and cooler bin intercommunication and local are located the cooler bin outside, the cooler bin outside the vertical funnel that is fixed with outside the cooler bin, the lower extreme of funnel is provided with the air inlet, be provided with wind-force heat dissipation mechanism above the air inlet in the funnel, wind-force heat dissipation mechanism's motion is controlled by the promotion of the air that gets into and upwards surge in the air inlet, this wind conduction formula waste heat utilization structure utilizes the heat energy that the coolant liquid produced to make funnel and wind-force heat dissipation mechanism function cool down, reduce extra energy resource consumption.

Description

Air guide type waste heat utilization structure

Technical Field

The utility model relates to a waste heat recovery utilizes technical field, specifically is a wind guide formula waste heat utilization structure.

Background

The existing servers are increasingly powerful, the requirement for cooling the servers is gradually becoming strict, and the traditional air cooling cannot meet the increasing heat dissipation requirement of the servers, so that the server is soaked in a cooling box filled with cooling liquid to become a main solution, the cooling liquid needs to be additionally provided with a cooling device for cooling the server, and most cooling devices in the market at present need to be powered by an external supply device for operation.

Chinese patent application No. CN201910111026.6 discloses an immersion liquid cooling tank and a cooling device, which includes a tank body, a cooling liquid disposed in the tank body, a liquid flow pipe having an adjusting member disposed inside the tank body, and a pump body and a heat exchanger connected to the liquid flow pipe.

The cooling liquid in the immersed liquid cooling tank and the cooling device enters the tank body through the liquid flowing pipe under the action of the pump body, exchanges heat with the heating element, is heated, then flows out of the tank body, exchanges heat with the external heat exchanger, is cooled, then enters the tank body and flows to the heating element, but the flowing of the cooling liquid and the operation of the heat exchanger need to be supported by power supplied by the external supply device, and the energy consumption is high.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a wind conduction formula waste heat utilization structure, the heat energy that utilizes the coolant liquid to produce makes the function of ventilation duct and wind-force heat dissipation mechanism cool down, reduces extra energy resource consumption.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides a wind conduction formula waste heat utilization structure, includes the cooler bin and sets up the condensation structure on the cooler bin, the condensation structure includes the condenser pipe, the condenser pipe just is located the cooler bin outside with cooler bin intercommunication locally, outside the cooler bin outside the condenser pipe vertically be fixed with a chimney, the lower extreme of chimney is provided with the air inlet, be provided with wind-force heat dissipation mechanism in the chimney above the air inlet, wind-force heat dissipation mechanism's motion is controlled by the promotion of the air that gets into and upwards surge from the air inlet.

By adopting the scheme, compared with the prior art that the operation of the cooling device needs to be pushed by an external supply device connected with the cooling device, the energy consumption is higher, in the scheme, the temperature of the cooling liquid is increased after heat exchange with the heating element to generate cooling liquid steam, the cooling liquid steam enters the condenser pipe, the heat of the cooling liquid steam is guided out between the condenser pipe and the ventilating duct by the condenser pipe, so that the temperature of the air between the condenser pipe and the ventilating duct is increased, the generated hot air flows upwards through the ventilating duct due to lower density, the pressure between the condenser pipe and the ventilating duct is reduced, and at the moment, the external cold air enters the ventilating duct to supplement pressure, so that air circulation is formed, the air flow velocity on the outer wall of the condenser pipe is increased, and the heat dissipation efficiency is improved; meanwhile, air entering from the air inlet and surging upwards along the ventilating duct drives the wind power heat dissipation mechanism located in the ventilating duct to operate, the air flow speed is further increased, the heat dissipation efficiency is improved, and condensed cooling liquid falls back to the cooling box along the inner wall of the condensing pipe for cyclic utilization.

Furthermore, the wind power heat dissipation mechanism comprises a rotating shaft which is vertically and rotatably arranged from the outer wall of the condensation pipe or the inner wall of the ventilating duct and fan blades which are vertically and outwardly arranged on the outer ring wall of the rotating shaft.

By adopting the scheme, air entering from the air inlet and surging upwards pushes the fan blades to move so as to drive the rotating shaft connected with the fan blades to rotate, so that other fan blades positioned on the rotating shaft rotate axially around the rotating shaft, and the rotation of the wind power heat dissipation mechanism is realized.

Further, when the wind power heat dissipation mechanism is arranged on the outer wall of the condensation pipe, a stirring heat dissipation mechanism is arranged in the condensation pipe; when the wind power heat dissipation mechanism is arranged on the inner wall of the ventilating duct, the stirring heat dissipation mechanism is arranged outside the ventilating duct.

By adopting the scheme, when the stirring heat dissipation mechanism is arranged in the condensation pipe, the flow of the cooling liquid steam in the condensation pipe can be promoted, and the heat exchange efficiency of the cooling liquid steam is increased; when the stirring heat dissipation mechanism is arranged outside the ventilating drum, the flow of air outside the ventilating drum can be promoted, and the mixing of hot air and cold air near the ventilating drum is promoted to carry out external cooling.

Furthermore, the stirring and heat-radiating mechanism comprises a driven shaft and stirring blades which are vertically and outwardly arranged on the outer ring wall of the driven shaft, when the stirring and heat-radiating mechanism is arranged in the condensing pipe, the driven shaft and the rotating shaft are integrally arranged, and one end of the rotating shaft, which is close to the condensing pipe, extends into the condensing pipe; when the stirring heat dissipation mechanism is arranged outside the ventilating drum, the driven shaft and the rotating shaft are integrally arranged, and one end of the rotating shaft, which is close to the ventilating drum, extends out of the ventilating drum.

By adopting the scheme, the rotating shaft rotates to drive the driven shaft which is integrally arranged to rotate, and the stirring blade connected with the driven shaft axially rotates around the driven shaft, so that the rotation of the stirring heat dissipation mechanism is realized.

Furthermore, the flabellum and stirring leaf are provided with at least one group along the outer anchor ring circumference of pivot and driven shaft circumference even interval respectively.

Adopt above-mentioned scheme, set up a set of stirring that can realize the interior outer air current of condenser pipe or air funnel, promote gas flow, set up the multiunit and can further promote stirring efficiency, increase the gas flow rate.

Furthermore, a plurality of groups of condensation pipes and ventilation tubes are arranged on the cooling box at intervals.

By adopting the scheme, the multiple groups of condensation pipes and the ventilation funnel operate simultaneously, and the heat exchange efficiency of the cooling liquid is increased.

Furthermore, multiple groups of wind power heat dissipation mechanisms and/or stirring heat dissipation mechanisms are uniformly arranged around the axial direction and/or the circumferential direction of the condensation pipe and/or the ventilation barrel at intervals.

By adopting the scheme, the stirring efficiency can be improved by arranging the multiple groups of wind power heat dissipation mechanisms and the stirring heat dissipation mechanism, and the gas flow speed is increased.

Furthermore, a limiting plate for limiting the movement of the ventilating duct is arranged above the cooling box.

By adopting the scheme, the limiting plate can avoid the wind power heat dissipation mechanism from being clamped due to the shaking of the ventilating duct, so that the wind power heat dissipation mechanism and the stirring heat dissipation mechanism are out of work.

Further, one end of the condensation pipe is sealed and the other end is inserted into the cooling box.

By adopting the scheme, one end is sealed to avoid the leakage of the cooling liquid, and the other end is inserted into the cooling box, so that the cooling liquid steam can enter the condensation pipe.

Compared with the prior art, the utility model discloses the beneficial effect who reaches is:

1. the condenser pipe is vertically fixed with a funnel outside the condenser pipe, the condenser pipe exports the heat of coolant liquid steam to between condenser pipe and the funnel, make the air between condenser pipe and the funnel heat up, the hot-air of production is because density is lower, up flow through the funnel, pressure between condenser pipe and the funnel reduces, carry out the repression in the outside cold air entering funnel this moment, thereby form the air current circulation, the air velocity on the condenser pipe outer wall has been increased, promote the radiating efficiency.

2. Add wind-force heat dissipation mechanism in the funnel, the air that upwards surges along the funnel from the air inlet entering orders about the wind-force heat dissipation mechanism function that is located the funnel, further increases the gas flow rate, increases the radiating efficiency, the coolant liquid after the condensation falls back to the cooling tank internal recycle along the condenser pipe inner wall, through 2 above-mentioned advantages, the heat energy that utilizes the coolant liquid to produce makes funnel and wind-force heat dissipation mechanism function cool down, reduces extra energy resource consumption.

Drawings

The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention, and together with the description serve to explain the invention and not to limit the invention. In the drawings:

fig. 1 is a top view of an air-guiding waste heat utilization structure of the present invention;

fig. 2 is a front view of the air-guiding waste heat utilization structure of the present invention;

fig. 3 is a cross-sectional view a-a of fig. 2.

In the figure: 1. a cooling tank; 2. a condenser tube; 3. a funnel; 4. an air inlet; 5. a rotating shaft; 6. a fan blade; 7. a driven shaft; 8. stirring blades; 9. and a limiting plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely 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, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Examples

An air guide type waste heat utilization structure comprises a cooling box 1 and a condensation structure arranged on the cooling box 1, wherein the condensation structure comprises a condensation pipe 2, the condensation pipe 2 is communicated with the cooling box 1 and is partially positioned outside the cooling box 1, one end of the condensation pipe 2 positioned outside the cooling box 1 is sealed, one end of the condensation pipe 2 inserted into the cooling box 1 is provided with an inlet for cooling liquid steam to enter, a ventilating duct 3 is vertically fixed outside the cooling box 1 and outside the condensation pipe 2, the lower end of the ventilating duct 3 is provided with an air inlet 4, a plurality of groups of condensation pipes 2 and ventilating ducts 3 are arranged on the cooling box 1 at intervals, 6 groups are arranged in the embodiment, a limiting plate 9 for limiting the movement of the ventilating duct 3 is arranged above the cooling box 1, the limiting plate 9 is arranged in an inverted U shape in the embodiment, two ends of the limiting plate are fixedly connected with the upper end face of the cooling box 1, the ventilating duct 3 and the air inlet 4 are arranged on the limiting plate 9 in an inserting way for fixing, a wind power heat dissipation mechanism is arranged above the air inlet 4 in the ventilating duct 3, the wind power heat dissipation mechanism comprises a rotating shaft 5 which is vertically and rotatably arranged on the outer wall of the condensing pipe 2 or the inner wall of the ventilating duct 3 and fan blades 6 which are vertically and outwardly arranged on the outer ring wall of the rotating shaft 5, the movement of the wind power heat dissipation mechanism is controlled by the push of air which enters from the air inlet 4 and flows upwards along the ventilating duct 3, when the wind power heat dissipation mechanism is arranged on the outer wall of the condensing pipe 2, a stirring heat dissipation mechanism is arranged in the condensing pipe 2, and the stirring heat dissipation mechanism comprises a driven shaft 7 which extends to the inside of the condensing pipe 2 from one end, close to the outer wall of the condensing pipe 2, of the rotating shaft 5 and stirring blades 8 which are vertically and outwardly arranged on the outer ring wall of the driven shaft 7; when wind power heat dissipation mechanism sets up on 3 inner walls of draft tube, be provided with stirring heat dissipation mechanism outside draft tube 3, stirring heat dissipation mechanism includes that the one end that rotation axis 5 is close to 3 inner walls of draft tube extends to the driven shaft 7 outside 3 and the stirring leaf 8 of perpendicular outside setting in the outer rampart of driven shaft 7, wind power heat dissipation mechanism and/or stirring heat dissipation mechanism are provided with the multiunit around the even interval of condenser pipe 2 and/or the axial and/or circumference of draft tube 3, be provided with 2 groups wind power heat dissipation mechanism and stirring heat dissipation mechanism on a set of condenser pipe 2 and draft tube 3 in the embodiment, and be located draft tube 3 and condenser pipe 2 respectively, flabellum 6 and stirring leaf 8 are provided with at least one group along the even interval of outer anchor ring circumference of pivot 5 and driven shaft 7 respectively, be provided with 3 groups in this embodiment.

When the heating element needs to be cooled, heat exchange is carried out between cooling liquid and the heating element, the temperature of the cooling liquid rises to generate cooling liquid steam, the cooling liquid steam moves upwards and enters the condensation pipe 2, the condensation pipe 2 guides the heat of the cooling liquid steam to a position between the condensation pipe 2 and the ventilating funnel 3, so that the temperature of air between the condensation pipe 2 and the ventilating funnel 3 is increased, the generated hot air flows upwards through the ventilating funnel 3 due to low density, the pressure between the condensation pipe 2 and the ventilating funnel 3 is reduced, at the moment, external cold air enters the ventilating funnel 3 through the air inlet 4 to supplement pressure, airflow circulation is formed, the airflow speed on the outer wall of the condensation pipe 2 is increased, and the heat dissipation efficiency is improved; meanwhile, air entering from the air inlet 4 and surging upwards along the ventilating funnel 3 orders about the function of the wind power heat dissipation mechanism located in the ventilating funnel 3, the wind power heat dissipation mechanism rotates to drive the stirring heat dissipation mechanism to rotate, so that the flow rate of gas inside and outside the condensing pipe 2 or the ventilating funnel 3 is increased, the heat dissipation efficiency is improved, and condensed cooling liquid falls back to the inner circulation of the cooling box 1 along the inner wall of the condensing pipe 2.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described in the foregoing embodiments, or equivalents may be substituted for elements thereof. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (9)

1. The utility model provides a wind conduction formula waste heat utilization structure, includes cooler bin (1) and sets up the condensation structure on cooler bin (1), its characterized in that: the condensation structure comprises a condensation pipe (2), the condensation pipe (2) is communicated with a cooling box (1) and is locally positioned outside the cooling box (1), a ventilating duct (3) is vertically fixed outside the condensation pipe (2) outside the cooling box (1), the lower end of the ventilating duct (3) is provided with an air inlet (4), a wind power heat dissipation mechanism is arranged above the air inlet (4) in the ventilating duct (3), and the movement of the wind power heat dissipation mechanism is controlled by the pushing of air entering from the air inlet (4) and surging upwards.

2. The wind guide type waste heat utilization structure of claim 1, wherein: the wind power heat dissipation mechanism comprises a rotating shaft (5) which is vertically and rotatably arranged from the outer wall of the condensation pipe (2) or the inner wall of the ventilating duct (3) and fan blades (6) which are vertically and outwardly arranged on the outer ring wall of the rotating shaft (5).

3. The wind guide type waste heat utilization structure of claim 2, wherein: when the wind power heat dissipation mechanism is arranged on the outer wall of the condensation pipe (2), a stirring heat dissipation mechanism is arranged in the condensation pipe (2); when the wind power heat dissipation mechanism is arranged on the inner wall of the ventilating duct (3), the stirring heat dissipation mechanism is arranged outside the ventilating duct (3).

4. The wind guide type waste heat utilization structure according to claim 3, characterized in that: the stirring heat dissipation mechanism comprises a driven shaft (7) and stirring blades (8) which are vertically and outwards arranged on the outer ring wall of the driven shaft (7), when the stirring heat dissipation mechanism is arranged in the condensation pipe (2), the driven shaft (7) and the rotating shaft (5) are integrally arranged, and one end of the rotating shaft (5) close to the condensation pipe (2) extends into the condensation pipe (2); when the stirring heat dissipation mechanism is arranged outside the ventilating duct (3), the driven shaft (7) and the rotating shaft (5) are integrally arranged, and one end of the rotating shaft (5) close to the ventilating duct (3) extends out of the ventilating duct (3).

5. The wind guide type waste heat utilization structure according to claim 4, wherein: at least one group of fan blades (6) and at least one group of stirring blades (8) are uniformly arranged along the circumferential direction of the outer ring surface of the rotating shaft (5) and the driven shaft (7) at intervals.

6. The wind guide type waste heat utilization structure of claim 5, wherein: a plurality of groups of condensation pipes (2) and ventilation tubes (3) are arranged on the cooling box (1) at intervals.

7. The wind guide type waste heat utilization structure of claim 6, wherein: multiple groups of wind power heat dissipation mechanisms and/or stirring heat dissipation mechanisms are uniformly arranged around the condensing pipe (2) and/or the ventilating duct (3) at intervals in the axial direction and/or the circumferential direction.

8. The wind guide type waste heat utilization structure of claim 1, wherein: a limiting plate (9) for limiting the movement of the ventilating duct (3) is arranged above the cooling box (1).

9. The wind guide type waste heat utilization structure of claim 1, wherein: one end of the condensation pipe (2) is sealed and the other end is inserted into the cooling box (1).

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