CN216011902U - Data center waste heat recovery utilizes device - Google Patents

Abstract

The utility model discloses a data center waste heat recycling device, which is arranged in a containing groove in the rear side surface of a cabinet body at the later stage for use; the method comprises the following steps: the water storage chamber is arranged above the supporting plate, and heat conduction copper sheets penetrate through and are fixed in the left side surface and the right side surface of the water storage chamber; the upper end of the second threaded rod penetrates through the middle inside of the supporting plate and the bottom surface of the water storage chamber and is connected with the top end inner bearing of the water storage chamber; wherein, the left and right sides of reservoir chamber all is provided with the silica gel gasbag. This data center waste heat recovery utilizes device is provided with the second threaded rod, and the second threaded rod can drive outside threaded connection's sleeve pipe when just reversing to go up and down, thereby make the sleeve pipe drive the removal pole in the outside stir the water in the water storage chamber, so that the water in the water storage chamber flows, the fine waste heat of being convenient for water is retrieved, makes water become hot, the later stage of being convenient for uses hot water, thereby is convenient for utilize the waste heat.

Description

Data center waste heat recovery utilizes device

Technical Field

The utility model relates to a data center technical field specifically is a data center waste heat recovery utilizes device.

Background

The data center transmits, displays and stores data through a series of devices and the Internet, and the devices in the data center generate a large amount of heat during working, so that devices for recycling and utilizing the heat are provided in the market, and waste of the heat is avoided;

most of the existing waste heat recovery devices recycle heat through cold water heat conduction, but the cold water has poor fluidity, and meanwhile, the installation position of the waste heat recovery device is fixed, so that the waste heat recovery efficiency is low;

therefore, the data center waste heat recycling device can well solve the problems.

Disclosure of Invention

An object of the utility model is to provide a data center waste heat recovery utilizes device to solve the most existing waste heat recovery device on the existing market that above-mentioned background art provided and carry out heat-conduction through cold water and come to carry out recycle to the heat, but the mobility of cold water is poor, and the position of waste heat recovery device installation is fixed simultaneously, consequently makes waste heat recovery's the slower problem of efficiency.

In order to achieve the above object, the utility model provides a following technical scheme: a data center waste heat recycling device is installed in a containing groove in the rear side face of a cabinet body at the later stage and used;

a containing groove is formed in the rear side face of the cabinet body main body, and a supporting plate is arranged in the containing groove;

the left end and the right end of the supporting plate are connected with the inside of the cabinet body through screws;

the method comprises the following steps:

the water storage chamber is arranged above the supporting plate, and heat conduction copper sheets penetrate through and are fixed in the left side surface and the right side surface of the water storage chamber;

the upper end of the second threaded rod penetrates through the middle inside of the supporting plate and the bottom surface of the water storage chamber and is connected with the top end inner bearing of the water storage chamber;

the outer side of the upper end of the second threaded rod is in threaded connection with a sleeve, and moving rods are fixed on the left side and the right side of the sleeve;

wherein, the left and right sides of reservoir chamber all is provided with the silica gel gasbag, and the bottom and the backup pad fixed connection of silica gel gasbag.

Preferably, the outside of silica gel gasbag is provided with first threaded rod, and the upper end of first threaded rod is connected with the inner bearing of cabinet body main part to the lower extreme of first threaded rod is connected with the inner bearing of backup pad, and the upper end outside threaded connection of first threaded rod has the clamp plate.

Through the arrangement of the structure, the first threaded rod drives the press plate to lift.

Preferably, the second threaded rod is connected with the middle inner part of the supporting plate and the bottom surface of the water storage chamber through sealing bearings.

Through the arrangement of the structure, the water in the water storage chamber is prevented from leaking out.

Preferably, the pressing plate forms a lifting structure through the first threaded rod, the lower surface of the pressing plate is in fit connection with the upper surface of the silica gel air bag, the two first threaded rods are symmetrically arranged on the vertical central line of the second threaded rod, and the lower ends of the two first threaded rods are connected with the lower end of the second threaded rod through a chain wheel mechanism.

Through the arrangement of the structure, the first threaded rod and the second threaded rod can rotate conveniently.

Preferably, an inlet and an outlet are fixed on the front side face of the lower end of the silica gel air bag, and the silica gel air bag can suck air and spit air convexly.

Through the arrangement of the structure, peripheral heat of the silica gel air bag can flow well.

Preferably, the front side of the first threaded rod is provided with a shielding plate, one end of the shielding plate is fixed with the inside of the cabinet body through a screw, and the inside of the shielding plate is in a mesh structure.

Through the arrangement of the structure, the shielding plate is enabled to be fine and limit the silica gel air bag, and the pressing plate is convenient to extrude the silica gel air bag well in the later period.

Preferably, the top of reservoir chamber is run through and is provided with inlet tube and outlet pipe, and the upper surface of cabinet body main part is all run through on the top of inlet tube and outlet pipe to the right side of inlet tube is provided with the outlet pipe.

Through the arrangement of the structure, the water inlet and the water drainage work are conveniently carried out on the inside of the water storage chamber.

Preferably, the locating slot has all been seted up to inside around the reservoir chamber, the side all is fixed with the slider around the carriage release lever, and slider and locating slot block sliding connection.

Through the arrangement of the structure, the sliding block is connected with the positioning groove in a clamping and sliding mode, so that the moving rod can stably lift.

Compared with the prior art, the beneficial effects of the utility model are that: the data center waste heat recycling device;

(1) the second threaded rod is arranged, and the second threaded rod can drive the sleeve in threaded connection with the outer side to lift when rotating positively and negatively, so that the sleeve drives the moving rod on the outer side to stir water in the water storage chamber, the water in the water storage chamber can flow conveniently, waste heat can be recovered well by the water, the water becomes hot, hot water can be used conveniently in the later period, and the waste heat can be utilized conveniently;

(2) the silica gel air bag and the pressing plate are fixed, and the silica gel air bag is intermittently extruded by the pressing plate, so that the silica gel air bag can suck peripheral air into the silica gel air bag, and long-distance heat can be conveniently sucked into the periphery of the water storage chamber, so that the heat of the peripheral air can be well contacted with the water storage chamber to enter the heat conduction, and the waste heat recovery efficiency is improved;

(3) through the arrangement of the chain wheel mechanism, the first threaded rod and the second threaded rod synchronously rotate, the use of a power source is reduced, and energy is saved.

Drawings

FIG. 1 is a schematic view of the main sectional structure of the present invention;

FIG. 2 is an enlarged schematic view of the structure at A of FIG. 1 according to the present invention;

FIG. 3 is a schematic top view of the sprocket mechanism of the present invention;

FIG. 4 is a schematic top view of the pressing plate of the present invention;

fig. 5 is a schematic view of the sectional structure of the water storage chamber.

In the figure: 1. a cabinet body; 2. a water inlet pipe; 3. a water outlet pipe; 4. a water storage chamber; 5. a thermally conductive copper sheet; 6. a containing groove; 7. a first threaded rod; 7-1, pressing a plate; 8. a support plate; 9. a second threaded rod; 10. a silica gel air bag; 10-1, an inlet and an outlet; 11. a sleeve; 12. positioning a groove; 13. a slider; 14. a travel bar; 15. a sprocket mechanism; 16. a shielding 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.

Referring to fig. 1-5, the present invention provides a technical solution: a data center waste heat recycling device is installed in a containing groove 6 in the rear side face of a cabinet body 1 at the later stage for use;

a containing groove 6 is formed in the rear side surface of the cabinet body 1, and a supporting plate 8 is arranged in the containing groove 6;

as shown in fig. 1, the whole waste heat recycling device is installed in a containing groove 6 formed in the rear side surface of the cabinet body 1, and then the whole waste heat recycling device can be used.

The left end and the right end of the supporting plate 8 are connected with the inside of the cabinet body 1 through screws;

the method comprises the following steps:

the water storage chamber 4 is arranged above the supporting plate 8, and heat conducting copper sheets 5 penetrate through and are fixed in the left side surface and the right side surface of the water storage chamber 4;

the upper end of the second threaded rod 9 penetrates through the middle inside of the supporting plate 8 and the bottom surface of the water storage chamber 4 and is connected with the top end inner bearing of the water storage chamber 4; wherein, the outer side of the upper end of the second threaded rod 9 is in threaded connection with a sleeve 11, and the left side and the right side of the sleeve 11 are both fixed with a movable rod 14;

as shown in the attached drawings 1-3, outside cold water enters the water storage chamber 4 through the water inlet pipe 2, then the servo motor at the bottom end of the second threaded rod 9 is connected with an outside power supply, the servo motor can drive the second threaded rod 9 to rotate forward and backward, so that the second threaded rod 9 drives the sleeve 11 and the moving rod 14 which are in threaded connection at the outer side to lift and descend reciprocally together, meanwhile, as shown in the attached drawings 1 and 5, the sliding blocks 13 at the front side and the rear side of the moving rod 14 are clamped in the positioning grooves 12, so that the sleeve 11 and the moving rod 14 lift stably, the moving rod 14 can stir the water in the water storage chamber 4, and the water in the water storage chamber 4 can flow well to recover heat at the periphery;

wherein, the left side and the right side of the water storage chamber 4 are both provided with silica gel airbags 10, the bottom ends of the silica gel airbags 10 are fixedly connected with the supporting plate 8, the outer side of the silica gel airbags 10 is provided with a first threaded rod 7, the upper end of the first threaded rod 7 is connected with the inner bearing of the cabinet body 1, the lower end of the first threaded rod 7 is connected with an inner bearing of the supporting plate 8, the outer side of the upper end of the first threaded rod 7 is in threaded connection with a pressing plate 7-1, the middle inner part of the second threaded rod 9 and the supporting plate 8 and the bottom surface of the water storage chamber 4 are connected through a sealing bearing, the pressing plate 7-1 forms a lifting structure through the first threaded rod 7, the lower surface of the pressing plate 7-1 is in fit connection with the upper surface of the silica gel air bag 10, and the number of the first threaded rods 7 is two about the vertical central line of the second threaded rod 9, and the lower ends of the two first threaded rods 7 are connected with the lower end of the second threaded rod 9 through a chain wheel mechanism 15.

The lower extreme leading flank of silica gel gasbag 10 is fixed with exit 10-1, and silica gel gasbag 10 can breathe in and the protruding gas of spitting, the front side of first threaded rod 7 is provided with shielding plate 16, and shielding plate 16's one end is fixed mutually through the screw with cabinet body 1's inside, and shielding plate 16's inside sets up for the mesh column structure, the top of reservoir chamber 4 is run through and is provided with inlet tube 2 and outlet pipe 3, and the upper surface of cabinet body 1 is all run through on inlet tube 2 and outlet pipe 3's top, and the right side of inlet tube 2 is provided with outlet pipe 3, constant head tank 12 has all been seted up to the inside around of reservoir chamber 4, the side all is fixed with slider 13 around the carriage release lever 14, and slider 13 and constant head tank 12 block sliding connection.

As shown in the attached drawings 1-3, when the second threaded rod 9 rotates, the first threaded rod 7 is driven to rotate through the chain wheel mechanism 15, the first threaded rod 7 is driven to rotate to drive the pressing plate 7-1 in threaded connection with the outer side to descend, the pressing plate 7-1 is used for extruding the silica gel air bag 10, gas in the silica gel air bag 10 is sprayed out through the inlet and the outlet 10-1, at this time, as shown in the attached drawing 4, the silica gel air bag 10 can be limited through the shielding plate 16 with the mesh-shaped structure inside, the silica gel air bag 10 is well extruded, then the pressing plate 7-1 is driven to ascend when the first threaded rod 7 rotates reversely, the pressure on the silica gel air bag 10 is removed, at this time, the silica gel air bag 10 automatically restores to the state, so that the silica gel air bag 10 sucks a part of air and heat around the silica gel air bag 10 into the silica gel air bag, at this time, the heat in the silica gel air bag 10 can be well conducted to water in the water storage chamber 4 through the heat conduction copper conduction sheet 5, make the temperature of the water in the reservoir chamber 4 uprise, so make the silica gel gasbag 10 reciprocate to breathe in and exhale, can flow the heat of long distance fine, be convenient for improve heat recovery's efficiency, the later stage is after heat recovery is good, takes out the water in the reservoir chamber 4 through the external suction pump of outlet pipe 3 cooperation and uses, can be used to daily life to be convenient for retrieve and utilize the waste heat.

The working principle is as follows: when the data center waste heat recycling device is used, firstly, external cold water enters the water storage chamber 4 through the water inlet pipe 2, and the second threaded rod 9 drives the sleeve 11 and the movable rod 14 which are in threaded connection with the outer side to reciprocate;

the second threaded rod 9 drives the first threaded rod 7 to rotate through the chain wheel mechanism 15, so that the silica gel air bag 10 sucks a part of air and heat at the periphery into the silica gel air bag, and then the heat in the silica gel air bag 10 can be well conducted to the water in the water storage chamber 4 through the heat conduction copper sheet 5, so that the temperature of the water in the water storage chamber 4 is increased, and the content which is not described in detail in the specification belongs to the prior art which is well known to a person skilled in the art.

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 or portions thereof without departing from the spirit and scope of the invention.

Claims (8)

1. A data center waste heat recycling device is installed in a containing groove (6) in the rear side face of a cabinet body (1) at the later stage for use;

a containing groove (6) is formed in the rear side face of the cabinet body main body (1), and a supporting plate (8) is arranged in the containing groove (6);

the left end and the right end of the supporting plate (8) are connected with the inside of the cabinet body (1) through screws;

it is characterized by comprising:

the water storage chamber (4) is arranged above the supporting plate (8), and heat conduction copper sheets (5) penetrate through and are fixed in the left side surface and the right side surface of the water storage chamber (4);

the upper end of the second threaded rod (9) penetrates through the middle inside of the supporting plate (8) and the bottom surface of the water storage chamber (4) and is connected with the top end inner bearing of the water storage chamber (4);

the outer side of the upper end of the second threaded rod (9) is in threaded connection with a sleeve (11), and moving rods (14) are fixed on the left side and the right side of the sleeve (11);

wherein, the left and right sides of reservoir chamber (4) all is provided with silica gel gasbag (10), and the bottom and backup pad (8) fixed connection of silica gel gasbag (10).

2. The data center waste heat recovery device of claim 1, wherein: the outer side of the silica gel air bag (10) is provided with a first threaded rod (7), the upper end of the first threaded rod (7) is connected with an inner bearing of the cabinet body main body (1), the lower end of the first threaded rod (7) is connected with an inner bearing of the supporting plate (8), and the outer side of the upper end of the first threaded rod (7) is in threaded connection with a pressing plate (7-1).

3. The data center waste heat recovery device of claim 1, wherein: the second threaded rod (9) is connected with the middle inner part of the supporting plate (8) and the bottom surface of the water storage chamber (4) through sealing bearings.

4. The data center waste heat recovery device of claim 2, wherein: the pressing plate (7-1) forms a lifting structure through the first threaded rod (7), the lower surface of the pressing plate (7-1) is in fit connection with the upper surface of the silica gel air bag (10), the first threaded rod (7) is symmetrically provided with two vertical central lines of the second threaded rod (9), and the lower ends of the two first threaded rods (7) are connected with the lower end of the second threaded rod (9) through the chain wheel mechanism (15).

5. The data center waste heat recovery device of claim 1, wherein: an inlet and an outlet (10-1) are fixed on the front side face of the lower end of the silica gel air bag (10), and the silica gel air bag (10) can suck air and spit air convexly.

6. The data center waste heat recovery device of claim 2, wherein: a shielding plate (16) is arranged on the front side of the first threaded rod (7), one end of the shielding plate (16) is fixed with the inside of the cabinet body (1) through a screw, and the inside of the shielding plate (16) is in a mesh structure.

7. The data center waste heat recovery device of claim 1, wherein: the top of reservoir chamber (4) runs through and is provided with inlet tube (2) and outlet pipe (3), and the top of inlet tube (2) and outlet pipe (3) all runs through the upper surface of cabinet body (1) to the right side of inlet tube (2) is provided with outlet pipe (3).

8. The data center waste heat recovery device of claim 1, wherein: locating slot (12) have all been seted up to inside around reservoir chamber (4), side all is fixed with slider (13) around carriage release lever (14), and slider (13) and locating slot (12) block sliding connection.

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