CN117693174B - Combined type tail end heat dissipation device of tower cooling pumping phase-change cooling system - Google Patents

Abstract

The invention discloses a combined type tail end heat dissipation device of a tower cooling pumping phase change cooling system, which relates to the technical field of phase change cooling and comprises two groups of air inlets, two first telescopic hoses, two longitudinal conductive sliding rails and two transverse conductive sliding rails.

Description

Combined type tail end heat dissipation device of tower cooling pumping phase-change cooling system

Technical Field

The invention relates to the technical field of phase-change cooling, in particular to a combined type tail end heat dissipation device of a tower cooling pumping phase-change cooling system.

Background

The existing data center cooling system generally comprises an outdoor unit and an indoor tail end, the indoor unit takes away heat in a machine room and conveys the heat to the outdoor unit through a connecting pipeline, the outdoor unit is discharged to an outdoor environment, the indoor unit is generally divided into a room level, a column level and a cabinet level, different equipment arrangement and equipment heating conditions can be selected, in the known cooling system, the indoor units corresponding to the same outdoor unit are all in the same form, the air supply temperature is generally kept consistent, different types of tail ends are required to be matched with different outdoor units, the continuous collocation is particularly time-consuming and labor-consuming in the process of adapting to use, the pipeline is not flexibly applicable to cabinets in different positions, when the cabinet is additionally installed and maintained, the heat dissipation requirement is changed, but the pipeline fixing universality effect is poor, the tail end heat dissipation device suitable for different indoor requirements is not conveniently selected according to the equipment heat dissipation requirement differentiation, the existing tail end heat dissipation device cannot be convenient to adjust the installation end, the installation suitability is poor, the accuracy is good, the refrigerating effect is not good, and the system energy efficiency is not well controlled.

Disclosure of Invention

The invention aims to provide a combined type tail end heat dissipation device of a tower cooling pumping phase change cooling system, which is used for solving the problems in the background technology.

In order to solve the technical problems, the invention adopts the following technical scheme: the utility model provides a tower cold pump sending phase transition cooling system combination formula end heat abstractor, includes two first flexible hoses of two sets of air intakes two indulge electrically conductive slide rail and two horizontal electrically conductive slide rail, first flexible hose communicates the both sides at the air intake through three way connection, indulge electrically conductive slide rail top both sides and all fixedly mounted have movable suspension piece, movable suspension piece is used for adjusting the installation height of indulging electrically conductive slide rail and horizontal electrically conductive slide rail, two indulge electrically conductive slide rail and two one side of horizontal electrically conductive slide rail is provided with first drive assembly and second drive assembly respectively, first drive assembly is used for driving horizontal electrically conductive slide rail and carries out vertical position adjustment, second drive assembly is used for adjusting the lateral position of nipple head on horizontal electrically conductive slide rail;

the bottom of the transverse conductive sliding rail is slidably provided with two groups of wind guide fixing boxes, one side of each wind guide fixing box is communicated with a connector, and a wind guide rotating pipe is rotatably arranged in each wind guide fixing box;

the top of the wind-guiding fixed box is provided with a single-drive double-acting mechanism which is used for independently driving the wind-guiding rotary pipe to conduct angle adjustment and height adjustment by adopting a driving source;

The top of the air guide rotary pipe is fixedly provided with a rotary angle driven component which is used for driving the air guide rotary pipe to twist the heat dissipation angle;

The top of the air guide rotary pipe is fixedly provided with a driven heat dissipation height adjusting mechanism, and the driven heat dissipation height adjusting mechanism is used for adjusting the height of the air guide rotary pipe by driven following the driving of the single-drive double-acting mechanism.

The technical scheme of the invention is further improved as follows: the movable suspension piece comprises a suspension plate, an electric push rod, a first shaft bracket and a second shaft bracket, wherein the suspension plate is arranged on an indoor roof, the electric push rod is fixedly arranged at the bottom of the suspension plate through bolts, the first shaft bracket is fixedly arranged at the output end of the electric push rod, the second shaft bracket is rotatably arranged at the bottom of the electric push rod through a shaft pin, and the bottom of the second shaft bracket is rotatably arranged at the top of the fixed plate through the shaft pin.

By adopting the technical scheme, the hanging plate can be installed on an indoor roof through the expansion screw, then the hanging plate can be avoided according to articles installed on the roof through the installation of the electric push rod, the electric push rod is started to drive the first shaft bracket and the second shaft bracket to move downwards, the second shaft bracket is used for driving the fixing plate to move downwards with the longitudinal conductive sliding rail, the transverse conductive sliding rail can not collide with a roof structure in the longitudinal movement process, the stability of driving is ensured, the installation suitability of equipment in various indoor environments is improved, and the installation height of the transverse conductive sliding rail and the longitudinal conductive sliding rail can be flexibly adjusted through the starting of the electric push rod after the installation.

The technical scheme of the invention is further improved as follows: the first driving assembly comprises a first stepping motor, a first bidirectional screw rod and a longitudinal driving block, the first stepping motor is fixedly arranged at one end of the longitudinal conductive sliding rail through a bolt, the first bidirectional screw rod is fixedly arranged at the output end of the first stepping motor through a coupler, the longitudinal driving block is in threaded connection with the surface of the first bidirectional screw rod, the longitudinal driving block is in sliding fit with the inner wall of the longitudinal conductive sliding rail, the top of the longitudinal driving block is in electric connection with the inner wall of the longitudinal conductive sliding rail, and the bottom of the longitudinal driving block is fixedly arranged at the top of the transverse conductive sliding rail.

By adopting the technical scheme, the first stepper motor can drive the first bidirectional screw rod to rotate after being started in the scheme, the longitudinal driving block which is limited by the longitudinal conductive sliding rail is driven by the rotating first bidirectional screw rod to carry out longitudinal movement adjustment, then the transverse conductive sliding rail is driven to carry out longitudinal movement, the longitudinal position of the connector at the bottom of the transverse conductive sliding rail is adjusted, the adjustment dimension is improved, and accurate heat dissipation is facilitated at multiple positions.

The technical scheme of the invention is further improved as follows: the pipeline tightening mechanism comprises a tightening ring, a mounting frame and an elastic rope, wherein the mounting frame is fixedly arranged on two sides of the bottom of the air inlet, the tightening ring is fixedly arranged on one end, far away from the air inlet, of the surface of the first telescopic hose, one end of the elastic rope is fixed with the mounting frame, and the other end of the elastic rope is fixed with the tightening ring;

The second driving assembly comprises a second stepping motor, a second bidirectional screw rod and a transverse driving block, the second stepping motor is fixedly arranged at one end of the transverse conductive sliding rail through a bolt, the second bidirectional screw rod is fixedly arranged at the output end of the second stepping motor through a coupler, the transverse driving block is in threaded connection with the surface of the second bidirectional screw rod, the transverse driving block is slidably arranged on the inner wall of the transverse conductive sliding rail, the top of the transverse driving block is electrically connected with the inner wall of the transverse conductive sliding rail, and the bottom of the transverse driving block is fixedly welded with the top of the connector.

By adopting the technical scheme, the second stepping motor can drive the second bidirectional screw rod to rotate after being started in the scheme, and the transverse driving block limited by the transverse conductive sliding rail is driven to carry out transverse position adjustment when the second bidirectional screw rod rotates, so that the heat dissipation position can be accurately adjusted.

The technical scheme of the invention is further improved as follows: the bottom of the air guide rotary pipe is communicated with a sealing rubber ring, ventilation grooves are formed in the periphery of the top of the surface of the air guide rotary pipe, the outer side of the sealing rubber ring is mounted with the inner wall of the air guide fixing box in a sealing mode, the bottom of the air guide rotary pipe is communicated with a second telescopic hose through the sealing rubber ring, and the bottom of the second telescopic hose is communicated with an air blowing head;

The single-drive double-acting mechanism comprises a fixing frame, a servo motor, a drive changing assembly, a bevel gear block and a height adjusting gear, wherein the fixing frame is fixedly arranged on one side, close to a nipple head, of the top of a wind guiding fixing box, the servo motor is fixedly arranged on the top of the fixing frame through bolts, the drive changing assembly is arranged on the output surface of the servo motor, the drive changing assembly is used for changing the drive position to respectively adjust the torsion angle and the height of a wind blowing head, the height adjusting gear is slidably sleeved on the output of the servo motor, a wedge-shaped groove is formed in a sliding position and is matched with the output end of the servo motor, and the bevel gear block is fixedly arranged on the bottom of the height adjusting gear.

By adopting the technical scheme, the fixing frame in the scheme can fix the servo motor, meanwhile, the driving range of the servo motor output end to the driving change assembly is provided, the height adjusting gear and the bevel gear block can be driven to rotate when the servo motor output end rotates through the wedge-shaped groove, and meanwhile, the height adjusting gear and the bevel gear block can slide up and down on the surface of the output end of the servo motor.

The technical scheme of the invention is further improved as follows: the drive change subassembly includes solid fixed ring, electromagnetic block, spring, magnetic attraction piece and lower solid fixed ring, go up solid fixed ring fixed mounting at the top of servo motor output surface, gu fixed ring's bottom at last solid fixed ring, the spring housing is established on the surface of servo motor output, gu fixed ring slip cap establishes the bottom at servo motor output surface down, gu fixed ring's bottom and the top fixed mounting of altitude mixture control gear down, the magnetic attraction piece slip cap is established on the surface of servo motor output, and bottom and lower solid fixed ring top fixed mounting, the magnetic attraction piece with the electromagnetic block magnetism after the circular telegram is inhaled the cooperation.

By adopting the technical scheme, the upper fixing ring can fix the electromagnetic block, and after the upper fixing ring is fixed with the output end of the servo motor, the upper fixing ring can generate magnetic force to be in magnetic attraction fit with the magnetic attraction block through the conductive electromagnetic block, the magnetic attraction block is lifted upwards, the effect of driving the height adjusting gear to be in meshed driving with the lifting driving gear is achieved, the height adjusting of the air blowing head is controlled after the lifting driving gear is driven, the electromagnetic block can be sleeved with the conductive slip ring at the output end of the servo motor to supply power in a rotating way, and when the heat dissipation torsion direction of the air guiding rotating pipe is required to be controlled, the electromagnetic block is powered off, the lower fixing ring is spring reset to downwards spring, at the moment, the height adjusting gear is driven to synchronously move downwards with the bottom bevel block to be meshed with the bevel meshing groove, the angle rotation control of the bevel meshing groove is achieved, and the air guiding rotating pipe can be driven to follow the torsion angle after the bevel meshing groove is rotated, so that the heat dissipation position is accurately controlled.

The technical scheme of the invention is further improved as follows: the rotary angle driven assembly comprises an angle driving connecting block and a bevel gear meshing groove, wherein the angle driving connecting block is fixedly arranged at the top of the wind guiding rotary pipe, and the bevel gear meshing groove is formed in the top of the angle driving connecting block and meshed with the bevel gear block.

By adopting the technical scheme, the angle driving connecting block in the scheme can enable the top of the wind guiding rotary pipe to be provided with the structure driven by the bevel gear block, and the bevel gear meshing groove is meshed with the bevel gear block, so that the bevel gear meshing groove can be driven by the bevel gear block to drive the angle driving connecting block to twist, and the wind guiding rotary pipe at the bottom is driven to twist through the twisting of the angle driving connecting block, so that the automatic adjustment of the heat dissipation angle of the wind guiding rotary pipe is realized.

The technical scheme of the invention is further improved as follows: the driven heat dissipation height adjusting mechanism comprises a torsion ring, a torsion plate, a stabilizing frame, a retainer, a driving shaft II and a driven winding and unwinding assembly, wherein the torsion ring is fixedly arranged at the top of the air guide rotary pipe, the torsion plate is welded on one side, away from the connector, of the torsion ring, the stabilizing frame is welded at the bottom of the torsion plate, the retainer is welded at the center of the bottom of the torsion plate, the driven winding and unwinding assembly is arranged at the top of the torsion plate, and the driven winding and unwinding assembly is used for winding and unwinding the heat dissipation height of the air blowing head.

By adopting the technical scheme, the torsion ring and the top of the wind-guiding rotary pipe are fixed, and then the torsion plate can twist with the wind-guiding rotary pipe with the angle changed, so that the second driving shaft and the driven winding and unwinding assembly are limited through the stabilizing frame and the retainer at the bottom of the torsion plate, and the driven winding and unwinding assembly is further forced to drive the bottom to be twisted to a required radiating angle by the second telescopic hose connected with the second telescopic hose, and meanwhile, the corresponding radiating height adjustment is carried out.

The technical scheme of the invention is further improved as follows: the driven winding and unwinding assembly comprises a lifting driving gear, a driving shaft I, a driven gear II, a worm, a driving shaft II, a worm wheel, a chain and a connecting ring, wherein the driving shaft is rotatably installed on one side of the top of a torsion plate, the lifting driving gear is fixedly installed on the top of one surface of the driving shaft, the driven gear I is connected to the bottom of one surface of the driving shaft and is located at the top of the torsion plate, the worm is rotatably installed in the torsion plate, the bottom of the worm is in rotary fit with a steady frame, the driven gear II is fixedly installed on the top of the worm surface, the driving shaft II is rotatably installed at the bottom of a retainer, the worm wheel is fixedly installed on one side, close to the worm, of the driving shaft II, and is meshed with the worm, the connecting ring is fixedly sleeved and fixed on the top of the surface of the blowing head, one end of the chain is welded on the surface of the driving shaft II, the other end of the chain is fixedly welded with the top of the connecting ring, the wind guide rotary pipe is rotatably capable of driving the torsion ring to follow torsion, and the blowing head can be forced to twist through the hardness of the chain at the moment, and the second telescopic hose on the top of the blowing head is relatively soft, and therefore, the driving flexible pipe can be driven to rotate by the wind guide head to rotate to the top by the hard and can rotate and the wind guide the chain to rotate.

By adopting the technical scheme, the first fixed driving shaft of the bottom driving shaft can transmit the rotating force meshed with the height adjusting gear to the first driven gear, the first driven gear drives the second driven gear meshed with the first driven gear to rotate, the second driven gear drives the worm fixed with the second driven gear to rotate simultaneously, the worm rotates to drive the worm wheel meshed with the worm, the self-locking effect is achieved through the matching structure of the worm and the worm wheel, the second driving shaft is driven to rotate when the worm wheel rotates, the second driving shaft rotates to drive the chain fixed with the second driving shaft to wind or unwind to achieve height adjustment, and the chain can not shake to two sides to misplacement when the chain is wound and unwound due to the limit of the retainer, so that the chain can not deviate when the chain is kept to break down and is blocked, the connecting ring can be driven to lift by the fixing of the connecting ring after the chain is wound and unreeled, the connecting ring lifts to enable the head to follow up and move to adjust the height, and due to the hardness of the chain, the torsion plate can drive the head to follow the corresponding heat dissipation angle when the torsion plate rotates, the torsion angle of the head is kept, the soft wind guide tube is kept, and the heat dissipation angle of the head is not synchronous to be controlled when the torsion angle of the head is adopted, and the heat dissipation rope is not capable of adopting the synchronous wind.

The technical scheme of the invention is further improved as follows: guide wheels are rotatably mounted on two sides of the bottom of the retainer through shaft pins, one side, close to a chain, of each guide wheel is in rotary fit with the chain, and each guide wheel is made of silica gel.

By adopting the technical scheme, the guide wheel in the scheme can guide the winding and unwinding of the chain, just enables the guide wheel to prop against two sides of the chain, has the supporting effect, simultaneously avoids the shaking when the chain is wound and unwound, and keeps the stability when the chain is wound and unwound.

By adopting the technical scheme, compared with the prior art, the invention has the following technical progress:

The invention provides a combined type tail end heat dissipation device of a tower cold pumping phase-change cooling system, which can drive a transverse conductive sliding rail and a connector to carry out plane multipoint movement through a first driving assembly and a second driving assembly, and simultaneously, a single-drive double-acting mechanism is matched with a rotation angle driven assembly and a driven heat dissipation height adjusting structure to carry out multidirectional three-dimensional position control on a blowing head.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic perspective view of a transverse conductive sliding rail according to the present invention.

Fig. 3 is a schematic perspective view of an air guide fixing case according to the present invention.

Fig. 4 is an exploded perspective view of the wind-guiding fixing case of the present invention.

Fig. 5 is an enlarged schematic view of fig. 1a according to the present invention.

Fig. 6 is an enlarged schematic view of fig. 4 at B in accordance with the present invention.

In the figure: 1. an air inlet; 2. a first flexible hose; 21. a tension ring; 22. a mounting frame; 23. an elastic rope; 3. a longitudinal conductive slide rail; 31. a first stepping motor; 32. a first bidirectional screw rod; 33. a longitudinal driving block; 4. a transverse conductive sliding rail; 41. a second stepping motor; 42. a second bidirectional screw rod; 43. a lateral drive block; 5. a nipple head; 51. an air guide fixing box; 52. a sealing rubber ring; 53. a second telescoping hose; 54. a blowing head; 55. an angle driving connecting block; 551. a torsion ring; 552. a torsion plate; 5521. a connecting ring; 5222. a lifting driving gear; 5523. a first driving shaft; 5524. a driven gear I; 5525. a driven gear II; 5526. a worm; 5527. a worm wheel; 55271. a second driving shaft; 5528. a stabilizing frame; 5529. a chain; 55201. a retainer; 55202. a guide wheel; 56. an air guide rotary pipe; 561. a ventilation groove; 57. a servo motor; 571. a fixing frame; 572. a bevel gear block; 573. a height adjusting gear; 5741. an upper fixing ring; 5742. an electromagnetic block; 5743. a spring; 5744. a magnetic suction block; 5745. a lower fixing ring; 575. bevel gear engagement groove; 6. a movable suspension member; 61. a hanging plate; 62. an electric push rod; 63. a first pedestal; 64. a second shaft frame; 65. and a fixing plate.

Detailed Description

The invention is further illustrated by the following examples:

example 1

As shown in fig. 1-6, the invention provides a device comprising two groups of air inlets 1, two first telescopic hoses 2, two longitudinal conductive sliding rails 3 and two transverse conductive sliding rails 4, wherein the two groups of air inlets 1 are arranged, the bottom of each air inlet 1 is fixedly provided with a pipeline tightening mechanism, each pipeline tightening mechanism comprises a tightening ring 21, a mounting frame 22 and elastic ropes 23, each mounting frame 22 is fixedly arranged on two sides of the bottom of each air inlet 1, each tightening ring 21 is fixedly arranged on one end, far away from the air inlet 1, of the surface of each first telescopic hose 2, one end of each elastic rope 23 is fixed with each mounting frame 22, the other end of each elastic rope 23 is fixed with each tightening ring 21, the first telescopic hose 2 is communicated with two sides of the air inlet 1 through a three-way joint, and movable suspension pieces 6 are fixedly arranged on two sides of the top of each longitudinal conductive sliding rail 3;

The movable suspension piece 6 comprises a suspension plate 61, an electric push rod 62, a first shaft bracket 63 and a second shaft bracket 64, the suspension plate 61 is mounted on an indoor roof, the electric push rod 62 is fixedly mounted at the bottom of the suspension plate 61 through bolts, the first shaft bracket 63 is fixedly mounted at the output end of the electric push rod 62, the second shaft bracket 64 is rotatably mounted at the bottom of the electric push rod 62 through a shaft pin, the bottom of the second shaft bracket 64 is rotatably mounted at the top of the fixed plate 65 through the shaft pin, the movable suspension piece 6 is used for adjusting the mounting heights of the longitudinal conductive sliding rail 3 and the transverse conductive sliding rail 4, one sides of the two longitudinal conductive sliding rails 3 and the two transverse conductive sliding rails 4 are respectively provided with a first driving component and a second driving component, and the first driving component is used for driving the transverse conductive sliding rail 4 to adjust the longitudinal position;

The first driving assembly comprises a first stepping motor 31, a first bidirectional screw rod 32 and a longitudinal driving block 33, wherein the first stepping motor 31 is fixedly arranged at one end of a longitudinal conductive sliding rail 3 through a bolt, the first bidirectional screw rod 32 is fixedly arranged at one end of the longitudinal conductive sliding rail 3 through a coupler, the longitudinal driving block 33 is in threaded connection with the surface of the first bidirectional screw rod 32, the longitudinal driving block 33 is slidably arranged on the inner wall of the longitudinal conductive sliding rail 3, the top is electrically connected with the inner wall of the longitudinal conductive sliding rail 3, the bottom of the longitudinal driving block 33 is fixedly arranged on the top of a transverse conductive sliding rail 4, the second driving assembly is used for adjusting the transverse position of a nipple 5 on the transverse conductive sliding rail 4, the second driving assembly comprises a second stepping motor 41, a second bidirectional screw rod 42 and a transverse driving block 43, the second stepping motor 41 is fixedly arranged at one end of the transverse conductive sliding rail 4 through a coupler, the transverse driving block 43 is in threaded connection with the surface of the second bidirectional screw rod 42, the transverse driving block 43 is slidably arranged on the inner wall of the transverse conductive sliding rail 4, the top of the transverse driving block 43 is electrically connected with the inner wall of the transverse conductive sliding rail 4, and the bottom of the transverse nipple 5 is electrically welded and fixedly connected with the bottom of the transverse conductive sliding rail 4;

The bottom of the transverse conductive sliding rail 4 is slidably provided with two groups of wind guide fixing boxes 51, one side of each wind guide fixing box 51 is communicated with a connector 5, a wind guide rotating pipe 56 is rotatably arranged in each wind guide fixing box 51, the bottom of each wind guide rotating pipe 56 is communicated with a sealing rubber ring 52, ventilation grooves 561 are formed in the periphery of the top of the surface of each wind guide rotating pipe 56, the outer side of each sealing rubber ring 52 is in sealing installation with the inner wall of each wind guide fixing box 51, the bottom of each wind guide rotating pipe 56 is communicated with a second telescopic hose 53 through the corresponding sealing rubber ring 52, and the bottom of each second telescopic hose 53 is communicated with a blowing head 54;

The top of the wind-guiding fixed box 51 is provided with a single-drive double-acting mechanism which is used for independently driving the wind-guiding rotary pipe 56 to perform angle adjustment and height adjustment by adopting a driving source;

the top of the air guide rotary pipe 56 is fixedly provided with a rotary angle driven component which is used for driving the air guide rotary pipe 56 to twist the heat dissipation angle;

the top of the air guiding rotary pipe 56 is fixedly provided with a driven heat dissipation height adjusting mechanism, and the driven heat dissipation height adjusting mechanism is used for adjusting the height of the air guiding rotary pipe 56 by driven following the driving of the single-drive double-acting mechanism.

In this embodiment, the suspension plate 61 can be mounted on the indoor roof through the expansion screw, then the mounting of the electric push rod 62 can be avoided according to the articles mounted on the roof, the electric push rod 62 is started to drive the first shaft bracket 63 and the second shaft bracket 64 to move downwards, the second shaft bracket 64 drives the fixing plate 65 and the longitudinal conductive sliding rail 3 to move downwards, the transverse conductive sliding rail 4 can not collide with the roof structure in the longitudinal moving process, the driving stability is ensured, and the mounting adaptability of the device in various indoor environments is improved;

The mounting height of the transverse conductive sliding rail 4 and the longitudinal conductive sliding rail 3 can be flexibly adjusted by starting the electric push rod 62 after mounting, the first stepper motor 31 can drive the first bidirectional screw rod 32 to rotate after being started, the first bidirectional screw rod 32 which rotates drives the longitudinal driving block 33 which is limited by the longitudinal conductive sliding rail 3 to carry out longitudinal movement adjustment, and then drives the transverse conductive sliding rail 4 to carry out longitudinal movement, the longitudinal position of the connector 5 at the bottom of the transverse conductive sliding rail 4 is adjusted, the adjustment dimension is improved, the precise heat dissipation is conveniently carried out at multiple positions, the second stepper motor 41 can drive the second bidirectional screw rod 42 to rotate after being started, and the transverse driving block 43 which is limited by the transverse conductive sliding rail 4 is driven to carry out transverse position adjustment when the second bidirectional screw rod 42 rotates, so that the heat dissipation position can be precisely adjusted.

Example 2

As shown in fig. 1-6, on the basis of embodiment 1, the present invention provides a technical solution: preferably, the single-drive double-acting mechanism comprises a fixing frame 571, a servo motor 57, a drive changing assembly, a bevel gear block 572 and a height adjusting gear 573, wherein the fixing frame 571 is fixedly arranged at one side, close to a connector head 5, of the top of the air guide fixing box 51, the servo motor 57 is fixedly arranged at the top of the fixing frame 571 through bolts, the drive changing assembly is arranged on the output surface of the servo motor 57, the drive changing assembly is used for changing the drive position to respectively adjust the torsion angle and the height of the air blowing head 54, the height adjusting gear 573 is arranged at the output of the servo motor 57 in a sliding sleeve mode, a wedge-shaped groove is formed in the sliding position to be matched with the output end of the servo motor 57, and the bevel gear block 572 is fixedly arranged at the bottom of the height adjusting gear 573;

the driving changing assembly comprises an upper fixing ring 5741, an electromagnetic block 5742, a spring 5743, a magnetic attraction block 5744 and a lower fixing ring 5745, wherein the upper fixing ring 5741 is fixedly arranged at the top of the output end surface of the servo motor 57, the electromagnetic block 5742 is fixedly arranged at the bottom of the upper fixing ring 5741, the spring 5743 is sleeved on the output end surface of the servo motor 57, the lower fixing ring 5745 is slidably sleeved at the bottom of the output end surface of the servo motor 57, the bottom of the lower fixing ring 5745 is fixedly arranged at the top of a height adjusting gear 573, the magnetic attraction block 5744 is slidably sleeved on the output end surface of the servo motor 57, the bottom of the magnetic attraction block 5744 is fixedly arranged at the top of the lower fixing ring 5745, the magnetic attraction block 5744 is in magnetic attraction fit with the electrified electromagnetic block 5742, the rotating angle driven assembly comprises an angle driving connecting block 55 and a bevel engagement groove 575, the angle driving connecting block 55 is fixedly arranged at the top of the air guiding rotating pipe 56, and the bevel engagement groove 575 is arranged at the top of the angle driving connecting block 55 and is engaged with the bevel block 572;

The driven heat dissipation height adjusting mechanism comprises a torsion ring 551, a torsion plate 552, a firm frame 5528, a retainer 55201, a driving shaft two 55271 and a driven winding and unwinding assembly, wherein the torsion ring 551 is fixedly arranged at the top of the air guide rotary pipe 56, the torsion plate 552 is welded at one side of the torsion ring 551 far away from the connector 5, the firm frame 5528 is welded at the bottom of the torsion plate 552, the retainer 55201 is welded at the center of the bottom of the torsion plate 552, the driven winding and unwinding assembly is arranged at the top of the torsion plate 552, and the driven winding and unwinding assembly is used for winding and unwinding the heat dissipation height of the air blowing head 54;

The driven winding and unwinding assembly comprises a lifting driving gear 5222, a driving shaft I5523, a driven gear I5524, a driven gear II 5525, a worm 5526, a driving shaft II 55271, a worm wheel 5527, a chain 5529 and a connecting ring 5521, wherein the driving shaft I5523 is rotatably mounted on one side of the top of the torsion plate 552, the lifting driving gear 5222 is fixedly mounted on the top of the surface of the driving shaft I5523, the driven gear I5524 is connected on the bottom of the surface of the driving shaft I5523 and is positioned on the top of the torsion plate 552, the worm 5526 is rotatably mounted in the torsion plate 552, the bottom is in rotary fit with a stabilizing frame 5528, the driven gear II 5525 is fixedly mounted on the top of the surface of the worm 5526, the driving shaft II 55271 is rotatably mounted on the bottom of a retainer 55201, the worm wheel 5527 is fixedly mounted on one side, close to the worm 5526, and is meshed with the worm 5526, the connecting ring 5521 is fixedly sleeved on the top of the surface of the blowing head 54, one end of the chain 5529 is welded on the surface of the driving shaft II 55271, the other end of the chain 5529 is fixedly welded on the top of the connecting ring 5521, two sides of the top of the connecting ring 5521, the retainer 55201 is rotatably mounted on the bottom 202, and the guide wheel 202 is rotatably mounted on one side, which is close to the guide wheel 5529 is rotatably mounted on one side of the chain 5529 through the guide wheel 5529, and the guide wheel 5529.

In this embodiment, the fixing frame 571 can fix the servo motor 57, meanwhile, provide the driving range of the driving changing component of the output end of the servo motor 57, and drive the height adjusting gear 573 and the bevel block 572 to rotate while rotating the output end of the servo motor 57 through the wedge groove, meanwhile, the height adjusting gear 573 and the bevel block 572 can slide up and down on the surface of the output end of the servo motor 57, the upper fixing ring 5741 can fix the electromagnetic block 5742, and after being fixed with the output end of the servo motor 57, the electromagnetic block 5742 can generate magnetic force to magnetically attract and cooperate with the magnetic attraction block 5744 through the conductive electromagnetic block 5742, so as to lift the magnetic attraction block 5744 upwards, realize the effect of driving the height adjusting gear 573 and the lifting driving gear 5222 to realize the height adjustment of the control blowing head 54 after driving the lifting driving gear 5222, and the electromagnetic block 5742 can be sleeved with the conductive slip ring to rotate and supply power through the output end of the servo motor 57;

When the heat dissipation torsion direction of the air guide rotary pipe 56 needs to be controlled, the electromagnetic block 5742 is powered off, the spring 5743 is reset to enable the lower fixing ring 5745 to spring downwards, and at the moment, the height adjusting gear 573 and the bottom bevel block 572 are driven to synchronously move downwards to be meshed with the bevel gear meshing groove 575, so that the angle rotation control of the bevel gear meshing groove 575 is realized, the air guide rotary pipe 56 can be driven to follow the torsion angle after the bevel gear meshing groove 575 rotates, and the effect of accurately controlling the heat dissipation position is achieved;

The angle driving connecting block 55 can enable the top of the air guiding rotary pipe 56 to be provided with a structure driven by the bevel block 572, the bevel block 572 can be driven by the bevel block 572 to drive the angle driving connecting block 55 to twist after the bevel block 572 is meshed with the bevel block 572, then the torsion of the angle driving connecting block 55 drives the air guiding rotary pipe 56 at the bottom to twist so as to realize the driven adjustment of the heat radiation angle of the air guiding rotary pipe 56, the torsion ring 551 is fixed with the top of the air guiding rotary pipe 56 and then can enable the torsion plate 552 to twist with the air guiding rotary pipe 56 with the angle changing, thereby limiting the driving shaft two 55271 and the driven winding and unwinding assembly through the stabilizing frame 5528 at the bottom of the torsion plate 552 and the retainer 55201, further forcing the driven winding and unwinding assembly to drive the bottom to be twisted to a required heat radiation angle by the second telescopic hose 53 connected with the second telescopic hose 53, and carrying out the corresponding heat radiation height adjustment, the first 5523 fixed by the driving shaft 6222 can transmit the rotation force meshed with the height adjusting gear 553 to the driven gear 5524, and then the driven gear 5526 is driven by the first worm gear 5524 to rotate and then the driven gear 5526 to rotate with the driven gear 5526, and the driven gear 5526 is meshed with the driven gear 5526, and the driven mechanism 5526 is rotated by the self-locking mechanism 5526, and the driven mechanism is meshed with the driven by the driven mechanism, and the driven mechanism 5527, and the driven mechanism is rotated by the driven mechanism;

The worm wheel 5527 drives the driving shaft II 55271 to rotate when rotating, the driving shaft II 55271 rotates to drive the chain 5529 fixed with the driving shaft II 55271 to wind or unwind to realize height adjustment, and the limit of the retainer 55201 ensures that the chain 5529 cannot shake and misplacement to two sides when winding and unwinding, the chain 5529 cannot deviate, failure and clamping are avoided, the chain 5529 can be lifted and lowered through the connecting ring 5521 driven by fixing the connecting ring 5521 after winding and unwinding, the connecting ring 5521 lifts and lowers the air blowing head 54 to move up and down to adjust the heat dissipation height, and due to the hardness of the chain 5529, the torsion plate 552 can drive the air blowing head 54 to follow the heat dissipation angle corresponding to torsion when rotating along with the torsion ring 551, the heat dissipation angle of the air guiding rotating pipe 56 and the air blowing head 54 is kept to be up and down synchronous, the heat dissipation angle of the soft winding and unwinding is avoided, the guide wheel 55202 can conduct winding and unwinding guidance on the chain 5529, the guide wheel 55202 is just abutted to two sides of the chain 5529, and the supporting effect is avoided when winding and unwinding the chain 5529 is ensured.

Example 3

As shown in fig. 1-6, on the basis of embodiment 1 and embodiment 2, the present invention provides a technical solution: the first driving assembly comprises a longitudinal driving block 33, the longitudinal driving block 33 is used as an electric sliding block, independent position driving of the plurality of longitudinal driving blocks 33 is carried out through electric matching of the electric sliding block and the longitudinal conductive sliding rail 3, the second driving assembly further comprises a transverse driving block 43 replaced by the electric sliding block, the transverse driving block 43 is electrically matched with the transverse conductive sliding rail 4 and used for independently driving the transverse positions of the plurality of connector heads 5, the application effect of indoor complex environments is improved, a magnetic block is arranged at one end of the air blowing head 54 far away from the connector heads 5, and the magnetic block is connected with the indoor tail end in a magnetic attraction mode;

In this embodiment, the longitudinal driving block 33 and the transverse driving block 43 of the electric sliding block can be respectively matched with the longitudinal conductive sliding rail 3 and the transverse conductive sliding rail 4 to perform multi-point movement control, which is different from the embodiment of the air inlet 1 in which the first stepping motor 31 and the first bidirectional screw rod 32 are matched, the electric sliding block can be adopted when the electric sliding block is suitable for multiple ends, the electric sliding block can be used for multiple indoor ends to perform cooling and heat dissipation when the electric sliding block is suitable for multiple ends, the effect of flexible control is further achieved, meanwhile, the longitudinal driving block 33 of the electric sliding block can be used for setting more indoor ends to achieve control of multiple indoor ends, and meanwhile, the magnetic blocks mounted through the air blowing head 54 are matched with the electric sliding block to perform quick magnetic attraction matching with different indoor ends, so that the connection speed is improved, and the flexible matching efficiency is improved for a large number of heat dissipation end control.

The working principle of the combined type tail end heat dissipation device of the tower cooling pumping phase change cooling system is specifically described below.

As shown in fig. 1-6, the hanging plate 61 is firstly fixed on an indoor roof through an expansion screw, then the installation of the electric push rod 62 can avoid according to articles installed on the roof, the electric push rod 62 is started to drive the first shaft bracket 63 and the second shaft bracket 64 to move downwards, the second shaft bracket 64 drives the fixing plate 65 to move downwards with the longitudinal conductive sliding rail 3, the transverse conductive sliding rail 4 can not collide with the roof structure in the longitudinal moving process, the driving stability is ensured, the installation suitability of equipment in various indoor environments is improved, and the installation heights of the transverse conductive sliding rail 4 and the longitudinal conductive sliding rail 3 can be flexibly adjusted by starting the electric push rod 62 after the installation;

The first stepping motor 31 can drive the first bidirectional screw rod 32 to rotate after being started, the rotating first bidirectional screw rod 32 drives the longitudinal driving block 33 limited by the longitudinal conductive sliding rail 3 to longitudinally move and adjust, and then drives the transverse conductive sliding rail 4 to longitudinally move, the longitudinal position of the connector head 5 at the bottom of the transverse conductive sliding rail 4 is adjusted, the adjusting dimension is improved, the accurate heat dissipation is conveniently carried out at multiple positions, the second stepping motor 41 can drive the second bidirectional screw rod 42 to rotate after being started, the transverse driving block 43 limited by the transverse conductive sliding rail 4 is driven to transversely adjust the position when the second bidirectional screw rod 42 rotates, in addition, in the moving process, the first telescopic hose 2 can be elastically pulled and tightened through the fixing of the elastic rope 23 by matching with the tightening ring 21, and the elastic rope 23 is specifically installed at a plurality of positions corresponding to the surface of the first telescopic hose 2 to fuse one glue point, so that when the elastic rope 23 is tightened, the telescopic multi-section first telescopic hose 2 can be ensured to be kept in a tightening state;

After the plane position of the connector 5 is determined, an upper fixed ring 5741 is started or an upper fixed ring 5741 is closed according to the indoor heat dissipation end which is actually required to be connected, or a servo motor 57 is started, if the heat dissipation angle of the air blowing head 54 needs to be controlled, the lower fixed ring 5745 is driven to move downwards by a spring 5743 after the power supply of the electromagnetic block 5742 is disconnected, the lower fixed ring 5745 drives a height adjusting gear 573 and a bevel block 572 to be meshed with a bevel meshing groove 575 at the top of the angle driving connecting block 55 downwards, then the servo motor 57 is started, the height adjusting gear 573 and the bevel block 572 can be driven to rotate by the wedge-shaped groove of the output end and the height adjusting gear 573 and the bevel block 572, at the moment, the bevel block 572 drives the angle driving connecting block 55 to rotate by the bevel meshing groove 575 meshed with the bevel block 572, the angle driving connecting block 55 drives the air guiding rotary pipe 56 to twist, then the angle driving connecting block 55 is driven by the torsion ring 551 at the top, the torsion plate 552 is driven by the torsion angle driving connecting block 55 at the bottom of the chain 5529 limited by the retainer 55201, and then the chain 5529 is driven to twist the corresponding angle by the connecting ring 5521;

When the lifting control of the blowing head 54 is required, the electromagnetic block 5742 is started, the conductive electromagnetic block 5742 generates magnetic force to magnetically attract and match with the magnetic attraction block 5744, the magnetic attraction block 5744 is lifted upwards, the effect of driving the height adjusting gear 573 to be meshed with the lifting driving gear 5222 is achieved, at the moment, the servo motor 57 is restarted to drive the height adjusting gear 573 to rotate through a wedge-shaped groove at the output end, the height adjusting gear 573 rotates to drive the lifting driving gear 5222 meshed with the height adjusting gear 573 to rotate, the driven gear 5525 rotates to drive the worm 5526 fixed with the driven gear 5526 to rotate, the worm 5526 rotates to drive the worm wheel 5527 meshed with the worm 5527 to rotate, the self-locking effect is achieved through the matching structure of the worm 5526 and the worm wheel 5527, the height is not loosened after the height adjustment, and drive the rotation of drive shaft two 55271 when worm wheel 5527 rotates, drive shaft two 55271 rotation drives the chain 5529 fixed with it and carries out the rolling or unreels and realize high regulation, and can not rock the dislocation to both sides when making chain 5529 receive and unreel owing to the spacing of holder 55201, can not the off tracking when keeping receiving and unreeling, avoid chain 5529 to break out the card to die, and accessible after chain 5529 receive and unreel is fixed with link 5521 drive link 5521 lift, link 5521 lift makes the blowing head 54 follow and reciprocates and adjusts the heat dissipation height, carry out accurate heat dissipation to the indoor heat dissipation terminal that needs to dispel the heat, the indoor heat dissipation terminal of next is transferred rapidly again through above-mentioned step after the heat dissipation is accomplished, a plurality of indoor heat dissipation terminals can be flexibly applied.

The foregoing invention has been generally described in great detail, but it will be apparent to those skilled in the art that modifications and improvements can be made thereto. Accordingly, it is intended to cover modifications or improvements within the spirit of the inventive concepts.

Claims (10)

1. The utility model provides a cold pumping phase transition cooling system combination formula end heat abstractor of tower, includes two sets of air intakes (1), two first flexible hose (2), two indulge electrically conductive slide rail (3) and two electrically conductive slide rail (4) of horizontal, its characterized in that: the first telescopic hoses (2) are communicated with two sides of the air inlet (1) through tee joints, movable suspension pieces (6) are fixedly arranged on two sides of the top of the longitudinal conductive sliding rail (3), the movable suspension pieces (6) are used for adjusting the installation heights of the longitudinal conductive sliding rail (3) and the transverse conductive sliding rail (4), one sides of the longitudinal conductive sliding rail (3) and one side of the transverse conductive sliding rail (4) are respectively provided with a first driving component and a second driving component, the first driving components are used for driving the transverse conductive sliding rail (4) to carry out longitudinal position adjustment, and the second driving components are used for adjusting the transverse position of the connector (5) on the transverse conductive sliding rail (4);

The bottom of the transverse conductive sliding rail (4) is slidably provided with two groups of wind guide fixing boxes (51), one side of each wind guide fixing box (51) is communicated with a connector (5), a wind guide rotating pipe (56) is rotatably arranged in each wind guide fixing box (51), the top of each wind guide fixing box (51) is provided with a single-drive double-acting mechanism, and the single-drive double-acting mechanism is used for independently driving the wind guide rotating pipe (56) to conduct angle adjustment and height adjustment by adopting a driving source;

A rotation angle driven component is fixedly arranged at the top of the air guide rotary pipe (56) and is used for driving the air guide rotary pipe (56) to twist the heat dissipation angle;

The top of the air guide rotary pipe (56) is fixedly provided with a driven heat dissipation height adjusting mechanism, and the driven heat dissipation height adjusting mechanism is used for adjusting the height of the air guide rotary pipe (56) by driven following the driving of the single-drive double-acting mechanism.

2. The modular terminal heat sink for a tower cold pumped phase change cooling system of claim 1, wherein: the movable suspension piece (6) comprises a suspension plate (61), an electric push rod (62), a first shaft bracket (63) and a second shaft bracket (64), wherein the suspension plate (61) is installed on an indoor roof, the electric push rod (62) is fixedly installed at the bottom of the suspension plate (61) through bolts, the first shaft bracket (63) is fixedly installed at the output end of the electric push rod (62), the second shaft bracket (64) is installed at the bottom of the electric push rod (62) through shaft pin rotation, and the bottom of the second shaft bracket (64) is installed through shaft pin rotation with the top of the fixed plate (65).

3. The modular terminal heat sink for a tower cold pumped phase change cooling system of claim 1, wherein: the first driving assembly comprises a first stepping motor (31), a first bidirectional screw rod (32) and a longitudinal driving block (33), wherein the first stepping motor (31) is fixedly arranged at one end of the longitudinal conductive sliding rail (3) through a bolt, the first bidirectional screw rod (32) is fixedly arranged at the output end of the first stepping motor (31) through a coupler, the longitudinal driving block (33) is in threaded connection with the surface of the first bidirectional screw rod (32), the longitudinal driving block (33) is in sliding installation with the inner wall of the longitudinal conductive sliding rail (3), the top of the longitudinal driving block is in electric connection with the inner wall of the longitudinal conductive sliding rail (3), and the bottom of the longitudinal driving block (33) is fixedly arranged at the top of the transverse conductive sliding rail (4).

4. The modular terminal heat sink for a tower cold pumped phase change cooling system of claim 1, wherein: the device is characterized in that a pipeline tightening mechanism is fixedly arranged at the bottom of the air inlet (1), the pipeline tightening mechanism comprises a tightening ring (21), a mounting frame (22) and an elastic rope (23), the mounting frame (22) is fixedly arranged on two sides of the bottom of the air inlet (1), the tightening ring (21) is fixedly arranged on one end, far away from the air inlet (1), of the surface of the first telescopic hose (2), one end of the elastic rope (23) is fixed with the mounting frame (22), and the other end of the elastic rope is fixed with the tightening ring (21);

The second driving assembly comprises a second stepping motor (41), a second bidirectional screw rod (42) and a transverse driving block (43), the second stepping motor (41) is fixedly arranged at one end of the transverse conductive sliding rail (4) through a bolt, the second bidirectional screw rod (42) is fixedly arranged at the output end of the second stepping motor (41) through a coupler, the transverse driving block (43) is in threaded connection with the surface of the second bidirectional screw rod (42), the transverse driving block (43) is in sliding installation with the inner wall of the transverse conductive sliding rail (4), the top of the transverse driving block (43) is electrically connected with the inner wall of the transverse conductive sliding rail (4), and the bottom of the transverse driving block (43) is fixedly welded with the top of the connector (5).

5. The modular terminal heat sink for a tower cold pumped phase change cooling system of claim 1, wherein: the bottom of the air guide rotary pipe (56) is communicated with a sealing rubber ring (52), ventilation grooves (561) are formed in the periphery of the top of the surface of the air guide rotary pipe (56), the outer side of the sealing rubber ring (52) is in sealing installation with the inner wall of the air guide fixed box (51), the bottom of the air guide rotary pipe (56) is communicated with a second telescopic hose (53) through the sealing rubber ring (52), and the bottom of the second telescopic hose (53) is communicated with a blowing head (54);

The single-drive double-acting mechanism comprises a fixing frame (571), a servo motor (57), a drive changing assembly, a bevel gear block (572) and a height adjusting gear (573), wherein the fixing frame (571) is fixedly arranged on one side, close to a connector (5), of the top of a wind guiding fixing box (51), the servo motor (57) is fixedly arranged on the top of the fixing frame (571) through bolts, the drive changing assembly is arranged on the output surface of the servo motor (57), the drive changing assembly is used for changing the drive position to respectively adjust the torsion angle and the height of a blowing head (54), the height adjusting gear (573) is sleeved on the output of the servo motor (57) in a sliding mode, a wedge groove is formed in the sliding position to be matched with the output end of the servo motor (57), and the bevel gear block (572) is fixedly arranged on the bottom of the height adjusting gear (573).

6. The modular terminal heat sink for a tower cold pumped phase change cooling system of claim 5, wherein: the drive change subassembly includes solid fixed ring (5741), electromagnetism piece (5742), spring (5743), magnetism inhale piece (5744) and lower solid fixed ring (5745), go up solid fixed ring (5741) fixed mounting at the top of servo motor (57) output surface, gu fixed mounting is in the bottom of solid fixed ring (5741) on electromagnetism piece (5742), the surface at servo motor (57) output is established to spring (5743) cover, the bottom at servo motor (57) output surface is established to lower solid fixed ring (5745) slip cap, the bottom and the top fixed mounting of altitude mixture control gear (573) of fixed ring (5745) down, magnetism inhale piece (5744) slip cap and establish the surface at servo motor (57) output, and bottom and the fixed mounting in bottom top of fixed ring (5745) down, magnetism inhale piece (5744) and the magnet piece (5742) magnetism of after the circular telegram and cooperation.

7. The modular terminal heat sink for a tower cold pumped phase change cooling system of claim 5, wherein: the rotary angle driven assembly comprises an angle driving connecting block (55) and a bevel gear meshing groove (575), wherein the angle driving connecting block (55) is fixedly arranged at the top of an air guide rotary pipe (56), and the bevel gear meshing groove (575) is formed in the top of the angle driving connecting block (55) and is meshed with the bevel gear block (572).

8. The modular terminal heat sink for a tower cold pumped phase change cooling system of claim 1, wherein: driven high adjustment mechanism of heat dissipation includes torsion ring (551), twists reverse board (552), firm frame (5528), holder (55201), drive shaft two (55271) and driven receive and release subassembly, twist reverse the top of ring (551) fixed mounting at wind-guiding swivelling tube (56), twist reverse board (552) welding is in one side of keeping away from nipple (5) at twists reverse ring (551), firm frame (5528) welding is in the bottom of twisting reverse board (552), holder (55201) welding is in twists reverse board (552) bottom center department, driven receive and release subassembly sets up at the top of twisting reverse board (552), driven receive and release subassembly is used for receiving the heat dissipation height of control blowing head (54).

9. The modular terminal heat sink for a tower cold pumped phase change cooling system of claim 8, wherein: the driven winding and unwinding assembly comprises a lifting driving gear (5222), a driving shaft I (5523), a driven gear I (5524), a driven gear II (5525), a worm (5526), a driving shaft II (55271), a worm wheel (5527), a chain (5529) and a connecting ring (5521), wherein the driving shaft I (5523) is rotationally arranged at one side of the top of a torsion plate (552), the lifting driving gear (5222) is fixedly arranged at the top of the surface of the driving shaft I (5523), the driven gear I (5524) is connected at the bottom of the surface of the driving shaft I (5523) in a key way and is positioned at the top of the torsion plate (552), the worm (5526) is rotationally arranged in the interior of the torsion plate (552), the bottom of the worm is rotationally matched with a steady rest (5528), the driven gear II (5525) is fixedly arranged at the top of the surface of the worm (5526), the worm wheel II (5527) is fixedly arranged at the bottom of the retainer (55201), one side of the surface of the driving shaft II (55271) close to the surface of the worm (5526) and is fixedly connected with the top of the chain (5529) in a sleeved mode, and the other end of the chain (5526) is fixedly connected with the top of the chain (5529) in a sleeved mode.

10. The modular terminal heat sink for a tower cold pumped phase change cooling system of claim 9, wherein: guide wheels (55202) are rotatably mounted on two sides of the bottom of the retainer (55201) through shaft pins, one side, close to a chain (5529), of each guide wheel (55202) is in rotary fit with the chain (5529), and each guide wheel (55202) is made of silica gel.