CN116722501A - Energy-saving bus duct structure for large and medium-sized computing center - Google Patents

Abstract

The invention relates to the technical field of bus ducts, and discloses an energy-saving bus duct structure for a large and medium-sized computing center, which solves the problem of poor heat dissipation effect of the bus duct at present, and comprises a shell, wherein a heat dissipation mechanism is arranged in the shell, bus bars are equidistantly arranged in the shell through the heat dissipation mechanism, a dustproof mechanism is arranged at the bottom of the shell, a fixing mechanism is arranged at the top of the shell, the heat dissipation mechanism comprises a ventilation plate fixed in the shell, two support plates are symmetrically and fixedly arranged at the top of the ventilation plate, and the bus bars are arranged on the support plates; according to the invention, through the cooperation between the bidirectional screw rod and the screw sleeve as well as the sliding plate and the U-shaped round rod, when the bidirectional screw rod rotates, the two sliding plates can transversely move, and through the cooperation between the rotating column and the jacking column and the cooperation between the gear and the toothed plate, the two fan blades can transversely move and simultaneously rotate, so that the interior of the shell can be conveniently and fully cooled.

Description

Energy-saving bus duct structure for large and medium-sized computing center

Technical Field

The invention belongs to the technical field of bus ducts, and particularly relates to an energy-saving bus duct structure for a large and medium-sized computing center.

Background

Networking refers to extending the concept of the internet into the connection between physical devices and everyday objects, which devices embed electronic devices, network connections and other forms of hardware, can communicate and interact with others over a network, and can be monitored remotely; the definition of the Internet of things is continuously changed along with the fusion of a plurality of real-time technologies; these techniques include: the traditional fields of analytics, machine learning, commercialized sensors and embedded systems, wireless sensor networks, control systems, automation and the like are all conducive to realizing the Internet of things; in order to ensure stable and effective operation of the industrial Internet of things, a power supply system of the industrial Internet of things can adopt a bus for power supply.

The traditional bus duct can produce heat when working for a long time, usually sets up a plurality of thermovent and dispels the heat on the bus duct, and this mode is not good to the radiating effect of bus duct, leads to the bus duct inconvenient quick heat dissipation when the temperature is higher.

Disclosure of Invention

Aiming at the situation, in order to overcome the defects of the prior art, the invention provides an energy-saving bus duct structure for a large and medium-sized computing center, which effectively solves the problem that the heat dissipation effect of the bus duct is poor at present.

In order to achieve the above purpose, the present invention provides the following technical solutions: the energy-saving bus duct structure for the large and medium-sized computing center comprises a shell, wherein a heat dissipation mechanism is arranged in the shell, bus bars are equidistantly arranged in the shell through the heat dissipation mechanism, a dustproof mechanism is arranged at the bottom of the shell, and a fixing mechanism is arranged at the top of the shell;

the heat dissipation mechanism is including being fixed in the inside ventilating board of shell, and ventilating board's top symmetry fixed mounting has two backup pads, and female arranging is placed in the backup pad, and ventilating board's bottom symmetry fixed mounting has two risers, and two risers are all fixed in on the inside diapire of shell, and the symmetry is equipped with two slide between two risers, and the top of two slide is all rotated and is connected with the spliced pole, and the equal fixed mounting in top of two spliced poles has the spliced pole, equal fixed mounting has the flabellum on two spliced poles, and two flabellums all are located ventilating board's below.

Preferably, the two vertical plates are rotationally connected with a two-way screw rod, two threaded sleeves are symmetrically sleeved on the outer sides of the two-way screw rod and are respectively fixed at the bottoms of the two sliding plates, rollers are fixedly installed at the bottoms of the two threaded sleeves and are located on the inner bottom wall of the shell, two U-shaped round rods are symmetrically and fixedly installed inside the shell, and the two sliding plates are movably sleeved on the outer sides of the two U-shaped round rods.

Preferably, the inside fixed mounting of shell has the U template, and fixed mounting has the pinion rack on the U template, and the outside of two jack-posts is all fixed mounting has the gear, and two gears all are connected with the pinion rack meshing.

Preferably, the dustproof mechanism comprises a dustproof frame fixed at the bottom of the shell, the dustproof frame is communicated with the inside of the shell, a fixing frame is fixedly installed inside the dustproof frame, a dustproof net is arranged below the fixing frame, the top of the dustproof net is close to four corners, movable columns are fixedly installed at the positions, the top ends of the movable columns penetrate through the fixing frame and fixedly installed with the movable frame, the movable columns are movably connected with the fixing frame, springs are fixedly connected between the dustproof net and the fixing frame and are close to the four corners, and the springs are movably sleeved with the movable columns.

Preferably, a motor is fixedly arranged at the top of the fixing frame, a transmission shaft is fixedly arranged at the top of the motor, a bevel gear II is fixedly arranged at the top of the transmission shaft, a bevel gear III is fixedly arranged at the outer side of the bidirectional screw rod, and the bevel gear III is in meshed connection with the bevel gear II.

Preferably, the inside symmetry rotation of dustproof frame is connected with two pivots, and the equal fixed mounting in the outside of two pivots has the eccentric wheel, and two eccentric wheels all are located the top of movable frame, and the equal fixed mounting of one end that two pivots are close to each other has bevel gear IV, and the outside fixed mounting of transmission shaft has bevel gear one, and two bevel gears IV all are connected with bevel gear one meshing.

Preferably, the top of mount fixed mounting has U type frame, and transmission shaft and two pivots all pass U type frame, and transmission shaft and two pivots all are connected with U type frame rotation.

Preferably, the fixing mechanism comprises a top shell positioned at the top of the shell, two clamping plates are symmetrically and fixedly arranged in the top shell, the two clamping plates are respectively positioned right above the two supporting plates, and the two clamping plates are attached to the busbar.

Preferably, the outside symmetry fixed mounting of top shell has two curb plates one, and the outside symmetry fixed mounting of shell has two curb plates two, and two curb plates one are laminated with two curb plates two respectively, and curb plate one and curb plate two all are equipped with the side tank, and the internally mounted in two side tanks has the contour plate, installs the bolt between curb plate one and the curb plate two, and the bolt runs through the contour plate, and the outside of bolt is equipped with the nut that is located curb plate two bottoms.

Compared with the prior art, the invention has the beneficial effects that:

(1) According to the invention, through the cooperation between the bidirectional screw rod and the screw sleeve as well as the sliding plate and the U-shaped round rod, when the bidirectional screw rod rotates, the two sliding plates can transversely move, and through the cooperation between the rotating column and the jacking column and the cooperation between the gear and the toothed plate, the two fan blades can transversely move and simultaneously rotate, so that the interior of the shell can be conveniently and fully cooled;

(2) According to the invention, through the coordination between the motor and the transmission shaft and between the bevel gear II and the bevel gear III, the rotation of the bidirectional screw rod is facilitated, and through the coordination between the bevel gear I, the bevel gear IV and the rotation shaft, the continuous impact of the two eccentric wheels on the movable frame is facilitated, and through the coordination between the movable frame and the fixed frame and between the movable column and the spring, the dust screen can continuously vibrate, so that the dust screen is prevented from being blocked, and the dust-proof effect of the dust screen is improved.

(3) The side plate I and the side plate II are conveniently connected through the matching between the side plate I and the side plate II and the side groove and the construction plate, and the side plate I and the side plate II are conveniently fixed through the matching between the bolts and the nuts, so that the top shell is conveniently fixed at the top of the shell, and meanwhile, the two clamping plates are used for clamping the busbar, so that the busbar is conveniently and orderly arranged in the shell.

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 the invention and together with the embodiments of the invention, serve to explain the invention.

In the drawings:

FIG. 1 is a schematic diagram of an energy-saving bus duct structure for a large and medium-sized computing center;

FIG. 2 is a schematic cross-sectional view of the housing of the present invention;

FIG. 3 is a schematic diagram of a heat dissipation mechanism according to the present invention;

FIG. 4 is a schematic diagram of a bi-directional screw structure according to the present invention;

FIG. 5 is a schematic view of a skateboard structure according to the present invention;

FIG. 6 is a schematic view of a dust-proof mechanism according to the present invention;

FIG. 7 is a schematic view of a dust screen according to the present invention;

FIG. 8 is a schematic view of a fixing mechanism according to the present invention;

fig. 9 is a schematic diagram of a side plate one and a side plate two of the present invention in a disassembled structure.

In the figure: 1. a housing; 2. a heat dissipation mechanism; 201. a ventilation board; 202. a vertical plate; 203. a support plate; 204. a U-shaped plate; 205. a toothed plate; 206. a slide plate; 207. a U-shaped round rod; 208. a two-way screw rod; 209. a fan blade; 2010. a top column; 2011. a gear; 2012. a screw sleeve; 2013. a roller; 2014. rotating the column; 3. a dust-proof mechanism; 301. a dust-proof frame; 302. a dust screen; 303. bevel gears I; 304. a motor; 305. a U-shaped frame; 306. an eccentric wheel; 307. a spring; 308. a movable frame; 309. a transmission shaft; 3010. bevel gears II; 3011. bevel gears III; 3012. bevel gears IV; 3013. a movable column; 3014. a fixing frame; 3015. a rotating shaft; 4. a fixing mechanism; 401. a top shell; 402. a first side plate; 403. a bolt; 404. a tooling plate; 405. a nut; 406. a second side plate; 407. a clamping plate; 408. a side groove; 5. and a busbar.

Detailed Description

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

In the first embodiment, as shown in fig. 1-9, the invention comprises a shell 1, a heat dissipation mechanism 2 is arranged in the shell 1, a busbar 5 is equidistantly arranged in the shell 1 through the heat dissipation mechanism 2, a dustproof mechanism 3 is arranged at the bottom of the shell 1, and a fixing mechanism 4 is arranged at the top of the shell 1.

In the second embodiment, on the basis of the first embodiment, the heat dissipation mechanism 2 includes a ventilation plate 201 fixed inside the casing 1, two support plates 203 are symmetrically and fixedly installed at the top of the ventilation plate 201, a busbar 5 is placed on the support plates 203, two vertical plates 202 are symmetrically and fixedly installed at the bottom of the ventilation plate 201, the two vertical plates 202 are both fixed on the inner bottom wall of the casing 1, two sliding plates 206 are symmetrically arranged between the two vertical plates 202, rotary posts 2014 are rotatably connected to the tops of the two sliding plates 206, top posts 2010 are fixedly installed at the top ends of the two rotary posts 2014, fan blades 209 are fixedly installed at the bottom of the ventilation plate 201, a bidirectional screw rod 208 is rotatably connected between the two vertical plates 202, two threaded sleeves 2012 are symmetrically sleeved at the outer sides of the bidirectional screw rod 208 and are respectively fixed at the bottoms of the two sliding plates 206, rollers 2013 are fixedly installed at the bottoms of the two threaded sleeves 2012, the two rollers 2013 are both positioned at the inner bottom wall of the casing 1, two U-shaped rods 207 are fixedly installed at the inner sides of the casing 1, two U-shaped rods 207 are both fixedly installed at the tops of the two U-shaped brackets 205, two U-shaped gears 207 are both fixedly meshed with the two U-shaped brackets 2011, and two U-shaped brackets 204 are fixedly installed at the inner sides of the two U-shaped brackets 205;

firstly, when the bidirectional screw rod 208 rotates, the two sliding plates 206 are driven to move transversely along the two U-shaped round rods 207, and meanwhile, the two jacking columns 2010 and the fan blades 209 are driven to move transversely, and as the two gears 2011 are meshed with the toothed plate 205, the two jacking columns 2010 rotate, and finally the two fan blades 209 move transversely and rotate, so that the sufficient heat dissipation inside the shell 1 is realized.

The third embodiment is based on the first embodiment, the dustproof mechanism 3 comprises a dustproof frame 301 fixed at the bottom of the shell 1, the dustproof frame 301 is communicated with the inside of the shell 1, a fixing frame 3014 is fixedly installed inside the dustproof frame 301, a dustproof net 302 is arranged below the fixing frame 3014, movable columns 3013 are fixedly installed at the positions, close to four corners, of the top of the dustproof net 302, movable frames 308 are fixedly installed on the tops of the movable columns 3014, the movable columns 3013 are movably connected with the fixing frame 3014, springs 307 are fixedly connected at the positions, close to four corners, between the dustproof net 302 and the fixing frame 3014, the springs 307 are movably sleeved with the movable columns 3013, a motor 304 is fixedly installed at the top of the fixing frame 3014, a transmission shaft 309 is fixedly installed at the top of the motor 304, a bevel gear two 3010 are fixedly installed at the top of the transmission shaft 309, two shafts 3015 are fixedly installed at the outer sides of the two bevel gears 3011, two shafts 3015 are in meshed connection with the bevel gear two 3010, two shafts 3015 are fixedly installed at the outer sides of the two shafts 3015, two shafts 301306 are respectively, two shafts 3012 are fixedly installed at the two shafts 3012, and two shafts 309 are fixedly connected with one end of the two shafts 3014, and two shafts 309 are fixedly installed at the two shafts 309 are respectively, and two ends of the two shafts 309 are fixedly connected with one end of the transmission shaft 309 are respectively;

firstly, the motor 304 is started to drive the transmission shaft 309 to rotate, the bidirectional screw rod 208 is rotated through the meshing action of the bevel gear II 3010 and the bevel gear III 3011, the two rotating shafts 3015 are driven to rotate through the meshing action of the bevel gear I303 and the bevel gear IV 3012, at the moment, the two eccentric wheels 306 rotate to continuously strike the movable frame 308, and the dust screen 302 is continuously vibrated through the elastic action of the spring 307, so that the dust screen 302 is prevented from being blocked, and the dust-proof effect of the dust screen 302 is improved.

In the fourth embodiment, based on the first embodiment, the fixing mechanism 4 includes a top shell 401 located at the top of the housing 1, two clamping plates 407 are symmetrically and fixedly installed in the top shell 401, the two clamping plates 407 are respectively located right above the two supporting plates 203, the two clamping plates 407 are attached to the busbar 5, two side plates one 402 are symmetrically and fixedly installed at the outer side of the top shell 401, two side plates two 406 are symmetrically and fixedly installed at the outer side of the housing 1, the two side plates one 402 are attached to the two side plates two 406 respectively, side grooves 408 are formed in the side plates one 402 and the two side plates two 406, a template 404 is installed in the two side grooves 408, a bolt 403 is installed between the side plates one 402 and the two side plates two 406, the bolt 403 penetrates through the template 404, and nuts 405 located at the bottoms of the side plates two 406 are arranged at the outer side of the bolt 403;

firstly, a top shell 401 is placed on the top of a shell 1, meanwhile, two clamping plates 407 clamp and limit a busbar 5, at the moment, a side plate I402 is attached to a side plate II 406, then a contour plate 404 is placed in side grooves 408 on the side plate I402 and the side plate II 406, the side plate I402 is connected with the side plate II 406, then the side plate I402 and the side plate II 406 are fixed with the contour plate 404 through bolts 403 and nuts 405, the top shell 401 and the shell 1 are fixed, and finally, the busbar 5 is fixed, so that the busbar 5 is orderly arranged in the shell 1.

Claims (9)

1. An energy-saving bus duct structure for large and medium-sized computing centers, which comprises a shell (1) and is characterized in that: the novel dustproof device is characterized in that a heat dissipation mechanism (2) is arranged in the shell (1), a busbar (5) is equidistantly arranged in the shell (1) through the heat dissipation mechanism (2), a dustproof mechanism (3) is arranged at the bottom of the shell (1), and a fixing mechanism (4) is arranged at the top of the shell (1);

the heat dissipation mechanism (2) comprises a ventilation plate (201) fixed inside the shell (1), two support plates (203) are symmetrically and fixedly arranged at the top of the ventilation plate (201), a busbar (5) is placed on the support plates (203), two vertical plates (202) are symmetrically and fixedly arranged at the bottom of the ventilation plate (201), two sliding plates (206) are symmetrically arranged between the two vertical plates (202), rotary columns (2014) are rotatably connected to the tops of the two sliding plates (206), jacking columns (2010) are fixedly arranged at the top ends of the two rotary columns (2014), fan blades (209) are fixedly arranged on the two jacking columns (2010), and the two fan blades (209) are located below the ventilation plate (201).

2. The energy-saving bus duct structure for a large and medium-sized computing center of claim 1, wherein: two rotate between riser (202) and be connected with two-way lead screw (208), two swivel nuts (2012) have been cup jointed to the outside symmetry screw thread of two-way lead screw (208), the bottom of two slide (206) is fixed in respectively to two swivel nuts (2012), the bottom of two swivel nuts (2012) is all fixed mounting has gyro wheel (2013), two gyro wheels (2013) all are located the inside diapire of shell (1), the inside symmetry fixed mounting of shell (1) has two U type round bars (207), the outside of two U type round bars (207) is all movably sleeved to two slide (206).

3. The energy-saving bus duct structure for a large and medium-sized computing center of claim 1, wherein: the novel lifting device is characterized in that a U-shaped plate (204) is fixedly arranged in the shell (1), a toothed plate (205) is fixedly arranged on the U-shaped plate (204), gears (2011) are fixedly arranged on the outer sides of two jacking columns (2010), and the two gears (2011) are meshed with the toothed plate (205).

4. The energy-saving bus duct structure for a large and medium-sized computing center of claim 1, wherein: dustproof mechanism (3) are including being fixed in dust frame (301) of shell (1) bottom, the inside intercommunication of dust frame (301) and shell (1), the inside fixed mounting of dust frame (301) has mount (3014), the below of mount (3014) is equipped with dust screen (302), the top of dust screen (302) is close to the equal fixed mounting in four corners position and has movable post (3013), the top of movable post (3013) runs through mount (3014) and fixed mounting has movable frame (308), and movable post (3013) and mount (3014) swing joint, be close to equal fixedly connected with spring (307) in four corners position between dust screen (302) and mount (3014), spring (307) are cup jointed with movable post (3013) activity.

5. The energy-saving bus duct structure for a large and medium-sized computing center of claim 4, wherein: the top of mount (3014) fixed mounting has motor (304), and the top fixed mounting of motor (304) has transmission shaft (309), and bevel gear two (3010) are fixedly installed on the top of transmission shaft (309), and the outside fixed mounting of two-way lead screw (208) has bevel gear three (3011), and bevel gear three (3011) is connected with bevel gear two (3010) meshing.

6. The energy-saving bus duct structure for a large and medium-sized computing center of claim 5, wherein: the inside symmetry of dustproof frame (301) rotates and is connected with two pivots (3015), and the outside of two pivots (3015) is all fixed mounting has eccentric wheel (306), and two eccentric wheels (306) all are located the top of movable frame (308), and the one end that two pivots (3015) are close to each other is all fixed mounting has bevel gear four (3012), and the outside fixed mounting of transmission shaft (309) has bevel gear one (303), and two bevel gears four (3012) all are connected with bevel gear one (303) meshing.

7. The energy-saving bus duct structure for a large and medium-sized computing center of claim 6, wherein: the top of mount (3014) fixed mounting has U type frame (305), and transmission shaft (309) and two pivot (3015) all pass U type frame (305), and transmission shaft (309) and two pivot (3015) all are connected with U type frame (305) rotation.

8. The energy-saving bus duct structure for a large and medium-sized computing center of claim 1, wherein: the fixing mechanism (4) comprises a top shell (401) positioned at the top of the shell (1), two clamping plates (407) are symmetrically and fixedly arranged in the top shell (401), the two clamping plates (407) are respectively positioned right above the two supporting plates (203), and the two clamping plates (407) are attached to the busbar (5).

9. The energy-saving bus duct structure for a large and medium-sized computing center of claim 8, wherein: two side plates I (402) are symmetrically and fixedly arranged on the outer side of the top shell (401), two side plates II (406) are symmetrically and fixedly arranged on the outer side of the shell (1), the two side plates I (402) are respectively attached to the two side plates II (406), side grooves (408) are formed in the side plates I (402) and the side plates II (406), a worker plate (404) is arranged in the inner parts of the two side grooves (408), a bolt (403) is arranged between the side plates I (402) and the side plates II (406), the bolt (403) penetrates through the worker plate (404), and nuts (405) located at the bottoms of the side plates II (406) are arranged on the outer side of the bolt (403).