CN111629546A

CN111629546A - Multifunctional large-scale server cabinet

Info

Publication number: CN111629546A
Application number: CN202010507915.7A
Authority: CN
Inventors: 陈小青
Original assignee: 陈小青
Current assignee: GUANGZHOU RUILIN ELECTRICAL MACHINERY Co.,Ltd.
Priority date: 2020-06-05
Filing date: 2020-06-05
Publication date: 2020-09-04
Anticipated expiration: 2040-06-05
Also published as: CN111629546B

Abstract

The invention discloses a multifunctional large-scale server cabinet, belonging to the field of servers, comprising a cabinet body, wherein the bottom end of the back of the cabinet body is provided with a heat dissipation hole group, the back of the cabinet body is also embedded with a plurality of uniformly distributed active heat exchange balls, and under the action of the heat rise in the cabinet body, the multifunctional large-scale server cabinet simulates a perpetual motion machine, so that the heat control perpetual motion balls continuously run in the cabinet body and can present a certain clockwise rotation state without manually or mechanically adding external force under the condition of continuously generating heat, thereby continuously guiding the heat of the cabinet body outwards and being taken away by flowing liquid, and simultaneously, in the process, not only the heat dissipation is carried out, but also the heat control perpetual motion balls are controlled to rotate by the heat, and the process of consuming the heat is also compared with the prior art, the radiating efficiency of the heat in the cabinet body is obviously improved, and the influence of the heat on the electric elements in the cabinet body is further reduced.

Description

Multifunctional large-scale server cabinet

Technical Field

The invention relates to the field of servers, in particular to a multifunctional large-scale server cabinet.

Background

A server is one of computers that runs faster, is more heavily loaded, and is more expensive than a regular computer. The server provides calculation or application services for other clients (such as terminals like PC, smart phone, ATM and the like and even large equipment like train systems and the like) in the network. The server has high-speed CPU computing capability, long-time reliable operation, strong I/O external data throughput capability and better expansibility. Generally, a server has the capability of responding to a service request, supporting a service, and guaranteeing the service according to the service provided by the server. The server is used as an electronic device, and the internal structure of the server is very complex, but the difference with the internal structure of a common computer is not great, such as: cpu, hard disk, memory, system bus, etc.

Large-scale server rack, because internally mounted's electric elements is more, lead to the server when the operation, can produce a large amount of heats, because the heat production is more, the heat gathering that is difficult to in time give off leads to the electric elements life in the rack to reduce in the rack, simultaneously because high hot environment causes the whole functioning speed of server to reduce, and to the heat dissipation of server rack among the prior art, generally only outside mediation, the heat dissipation is slower.

Disclosure of Invention

1. Technical problem to be solved

The invention aims to provide a multifunctional large-scale server cabinet, which can imitate a perpetual motion machine under the action of heat rise in a cabinet body by arranging a heat-control perpetual motion ball, so that the heat-control perpetual motion ball can continuously run in the cabinet body and can present a certain clockwise rotation state without manually or mechanically adding external force under the condition of continuously generating heat, thereby continuously guiding the heat of the cabinet body to the outside and taking away the heat by flowing liquid.

2. Technical scheme

In order to solve the above problems, the present invention adopts the following technical solutions.

A multifunctional large-scale server cabinet comprises a cabinet body, wherein a heat dissipation hole group is arranged at the bottom end of the back of the cabinet body, a plurality of active heat exchange balls which are uniformly distributed are further inlaid on the back of the cabinet body, each active heat exchange ball comprises a heat removal end and a heat collection end, the heat removal ends are fixedly connected with the heat collection ends, the heat removal ends face the outer side of the cabinet body, the heat collection ends face the inner side of the cabinet body, a water cooling channel is arranged inside the cabinet body and comprises heat removal channels which are chiseled in the cabinet body and the heat removal ends, the heat removal channels are communicated with one another, flowing liquid is filled in the water cooling channel, a circulating channel which is positioned outside the cabinet body is connected between the two end parts of the water cooling channel, a condenser is arranged on the circulating channel, and heat control permanent moving balls are placed between the heat removal ends and the heat collection ends, the inner wall of the heat removing end is fixedly connected with a plurality of heat removing support rods which are uniformly distributed, the heat removing support rods are communicated with the heat removing channel, the inner wall of the heat collecting end is fixedly connected with a heat conducting end, one end of the heat removing support rod, which is close to the heat conducting end, is contacted with the heat control perpetual motion ball, and through the arrangement of the heat control perpetual motion ball, under the action of the heat rise in the cabinet body, the heat-controlled perpetual motion ball imitates a perpetual motion machine, so that under the condition that the heat is continuously generated by continuously running the heat-controlled perpetual motion ball in the cabinet body, the clockwise rotation state can be presented without adding external force manually or mechanically, thereby continuously guiding the heat of the cabinet body to the outside and being taken away by the flowing liquid, and simultaneously, not only the heat is radiated, meanwhile, the heat control permanent ball is controlled to rotate through heat, and the process of consuming heat is adopted, so that the radiating efficiency of the heat in the cabinet body is obviously improved compared with the prior art.

Furthermore, the heat removal channel in the cabinet body is located on one side of the center line outside the cabinet body, and the wall thickness of the cabinet body on the right side of the heat removal channel is 4-5 times of that of the left side of the heat removal channel, so that flowing liquid cannot be too close to the inner wall of the cabinet body, condensation of hot air in the cabinet body when encountering the inner wall of the cabinet body is effectively avoided, and the situation that electrical elements in the cabinet body are damaged due to condensation is effectively avoided.

Further, rack body, heat-collecting end and heat conduction end are heat conducting material and make, and the three heat conductivity improves gradually to can produce certain heat conduction gradient difference between the three, make the partial heat of gathering at rack body inner wall gather to heat conduction end department gradually, and then enter into heat accuse ball department forever, along with the slowly rotating of heat accuse ball forever, thereby the heat with gathering gradually is taken away by the mobile liquid to the guide of rack body outside.

Furthermore, the heat removal support rod comprises a hollow tube fixedly connected with the heat removal end and a hollow micro flat ball connected to the end of the hollow tube.

Further, the little oblate spheroid of cavity includes the setting end with hollow tube fixed connection and inlays the deformation end of keeping away from the one end middle part of hollow tube at the setting end, and during the use, mobile liquid can enter into and get into in the branch that goes hot to certain deformation takes place to the deformation end, thereby increases the area of contact with the heat accuse is moved forever the ball for the speed that heat was taken away on the heat accuse forever the ball.

Furthermore, the hollow tube and the shaping end are made of hard materials, and the deformation end is made of elastic materials, so that the deformation end can adapt to the shape of the outer surface of the thermal control perpetual motion ball, and the thermal control perpetual motion ball is in surface contact with the deformation end, so that the contact area is increased, and the heat dissipation speed of the thermal control perpetual motion ball is increased.

Furthermore, SLIPS self-repairing super-smooth coatings are coated on the outer surface of the thermal control perpetual motion ball, the outer surface of the deformation end and the inner wall of the heat conduction end, and the surfaces of the thermal control perpetual motion ball, the deformation end and the heat conduction end are super-smooth through the SLIPS self-repairing super-smooth coatings, so that the friction force between the thermal control perpetual motion ball and the deformation end and the friction force between the thermal control perpetual motion ball and the heat conduction end are remarkably reduced, and the rotation of the thermal control perpetual motion.

Further, the internal connection of hot accuse perpetual motion ball has the radiation ball, the radiation ball is including the in-connection ball that is located the central point, a plurality of evenly distributed's of in-connection ball outer end fixedly connected with hot accuse moves the pole, hot accuse moves pole outer end fixedly connected with half clean shot, adjacent two half clean shot contacts each other for hot accuse perpetual motion ball is when being heated, and a plurality of half clean shots are heated and make its inside trigger move the ball and drop the density that produces decurrent gravity impact great, thereby make the density of hot accuse perpetual motion ball atress great, thereby make hot accuse perpetual motion ball can present the pivoted state that does not stop, and the one end that the in-connection ball was kept away from to half clean shot and hot accuse perpetual motion ball fixed connection.

Furthermore, a ball containing cavity is formed in the joint of the semi-hollow ball and the thermal control moving rod, one end, close to the semi-hollow ball, of the thermal control moving rod is of a hollow structure, the ball containing cavity is communicated with the thermal control moving rod, and a trigger moving ball is placed in the hollow portion of the thermal control moving rod.

Furthermore, the hollow part of the thermal control rod is made of elastic material, after the thermal control rod which is close to one side of the heat-gathering end and the middle part of which is downward is heated, because the thermal control rod and the air in the ball containing cavity expand, the thermal control rod can expand along with the thermal control rod, the triggering moving ball is in interference fit with the thermal control rod, and the thermal control rod is communicated with the ball containing cavity, when the thermal control rod is not expanded, the triggering movable ball can be arranged in the thermal control rod, when the thermal control rod is expanded, the triggering movable ball falls into the ball containing cavity from the thermal control rod, when downward gravity impact is generated, the thermal control perpetual motion ball rotates clockwise, the next thermal control moving rod is close to the position where the central line is downward, the processes are also generated, when the cabinet body continuously operates, therefore, when heat is continuously generated, the heat-control permanent ball can be effectively ensured to always have a certain clockwise rotation effect.

3. Advantageous effects

Compared with the prior art, the invention has the advantages that:

(1) this scheme can be through the setting of the forever ball of thermal control, under this internal heat of rack effect that rises, imitate perpetual motion machine, make the forever ball of thermal control continuously move at the rack body, continuously under the thermal condition of production, do not need artificial or mechanical external force of interpolation to present certain clockwise pivoted state, thereby constantly guide the heat of rack body to the outside, and taken away by flowing liquid, simultaneously at this in-process, not only thermal giving off has been carried out, simultaneously through the forever ball rotation of thermal control, still be a heat consumption process, compare in prior art, show the internal thermal efficiency of giving off of improvement rack.

(2) This internal heat removal passageway of rack is located central line to this external one side of rack, and the rack body wall thickness on heat removal passageway right side is 4-5 times of heat removal passageway left side wall thickness for flowing liquid can not be too near apart from rack body inner wall, thereby effectively avoids this internal hot air of rack to meet rack body inner wall and takes place the condensation phenomenon, effectively avoids leading to the impaired condition of this internal electrical component of rack to take place because of the condensation.

(3) The rack body, gather hot junction and heat conduction end and be heat conducting material and make, and the three heat conductivity improves gradually to can produce certain heat conduction gradient difference between the three, make the partial heat of gathering at rack body inner wall gather to heat conduction end department gradually, and then enter into the permanent ball department of thermal control, along with the slowly rotating of the permanent ball of thermal control, thereby the heat with the gathering is taken away by the mobile liquid to the guide of rack body outside gradually.

(4) The heat removal support rod comprises a hollow tube fixedly connected with the heat removal end and a hollow micro flat ball connected to the end part of the hollow tube.

(5) The little oblate spheroid of cavity includes the setting end with hollow tube fixed connection and inlays the deformation end at the one end middle part that the hollow tube was kept away from to the setting end, and during the use, mobile liquid can enter into and go into to remove hot branch in to certain deformation takes place to the deformation end, thereby increases the area of contact with the ball is moved forever to the thermal control, and then accelerates the speed that the heat was taken away from on the ball is moved forever to the thermal control.

(6) The hollow tube is made with hard material with the setting end, and the deformation end is made for elastic material for the deformation end can adapt to the shape of heat accuse perpetual motion ball surface, thereby realizes the face contact with heat accuse perpetual motion ball, and then increases area of contact for the radiating rate of heat accuse perpetual motion ball.

(7) The outer surface of the thermal control perpetual motion ball, the outer surface of the deformation end and the inner wall of the heat conduction end are coated with SLIPS self-repairing super smooth coatings, and the surfaces of the thermal control perpetual motion ball, the deformation end and the heat conduction end are super smooth through the SLIPS self-repairing super smooth coatings, so that the friction force between the thermal control perpetual motion ball and the deformation end and between the thermal control perpetual motion ball and the heat conduction end is remarkably reduced, and the rotation of the thermal control perpetual motion ball is not.

(8) The internal connection of hot accuse perpetual motion ball has the radiation to move the ball, the radiation moves the ball including the in-connection ball that is located the central point, a plurality of evenly distributed's of in-connection ball outer end fixedly connected with hot accuse moves the pole, hot accuse moves pole outer end fixedly connected with half hollow ball, adjacent two half hollow balls contact each other, make hot accuse perpetual motion ball when being heated, it is great that a plurality of half hollow balls are heated to make its inside trigger move the ball and drop the density that produces decurrent gravity impact, thereby it is great to make the density of hot accuse perpetual motion ball atress, thereby make hot accuse perpetual motion ball can present the pivoted state that does not pause, and the one end that the in-connection ball was kept away from to half hollow ball and hot accuse perpetual motion ball fixed connection.

(9) The joint of the semi-hollow ball and the thermal control moving rod is provided with a ball containing cavity, one end of the thermal control moving rod, which is close to the semi-hollow ball, is of a hollow structure, the ball containing cavity is communicated with the thermal control moving rod, and the triggering moving ball is arranged in the hollow part of the thermal control moving rod.

(10) The hollow part of the thermal control rod is made of elastic material, after the thermal control rod which is close to one side of the heat gathering end and is downward in the middle is heated, the thermal control rod can be expanded along with the thermal control rod due to the fact that the thermal control rod and air in the ball containing cavity expand, the triggering moving ball is in interference fit with the thermal control rod and is communicated with the ball containing cavity, when the thermal control rod is not expanded, the triggering moving ball can be in the thermal control rod, when the thermal control rod expands, the triggering moving ball falls into the ball containing cavity from the thermal control rod, downward gravity impact is generated, the thermal control perpetual ball rotates clockwise, at the moment, the next thermal control rod is close to the part which enters the middle line downward, the processes are also generated, when the cabinet body continuously operates, and therefore when heat is continuously generated, the thermal control perpetual ball can be effectively guaranteed to always have a certain clockwise rotation effect.

Drawings

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic structural view of the back side of the present invention;

FIG. 3 is a schematic structural view of a portion of the thermal control perpetual motion ball of the present invention on the inner wall of the cabinet body;

FIG. 4 is a schematic structural view of a heat removal strut of the present invention;

FIG. 5 is a schematic structural diagram of a cross section of a thermally controlled perpetual motion ball of the present invention;

FIG. 6 is a schematic structural view of a portion of the thermally controlled rod of the present invention.

The reference numbers in the figures illustrate:

1 cabinet body, 2 radiating hole groups, 3 active heat exchange balls, 31 heat removal ends, 32 heat collection ends, 33 heat conduction ends, 4 heat removal channels, 6 heat removal supporting rods, 61 hollow tubes, 62 shaping ends, 63 deformation ends, 7 heat control permanent balls, 9 heat control moving rods, 10 half hollow balls, 11 ball containing cavities and 12 trigger moving balls.

Detailed Description

The drawings in the embodiments of the invention will be combined; the technical scheme in the embodiment of the invention is clearly and completely described; obviously; the described embodiments are only some of the embodiments of the invention; but not all embodiments, are based on the embodiments of the invention; all other embodiments obtained by a person skilled in the art without making any inventive step; all fall within the scope of protection of the present invention.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "top/bottom", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "disposed," "sleeved/connected," "connected," and the like are to be construed broadly, e.g., "connected," which may be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example 1:

referring to fig. 1-2, a multifunctional large-scale server cabinet includes a cabinet body 1, a heat dissipation hole group 2 is disposed at the bottom of the back of the cabinet body 1, a plurality of active heat exchange balls 3 are also embedded in the back of the cabinet body 1, a flowing liquid is filled in a water cooling channel, a circulation channel located outside the cabinet body 1 is connected between two end portions of the water cooling channel, and a condenser is installed on the circulation channel.

Referring to fig. 3, the active heat exchange ball 3 includes a heat removing end 31 and a heat collecting end 32, the heat removing end 31 is fixedly connected with the heat collecting end 32, the heat removing end 31 faces the outside of the cabinet body 1, the heat collecting end 32 faces the inside of the cabinet body 1, a water cooling channel is arranged inside the cabinet body 1, the water cooling channel includes a heat removing channel 4 cut in the cabinet body 1 and the heat removing end 31, the heat removing channel 4 in the cabinet body 1 is located at one side of the center line facing the outside of the cabinet body 1, the wall thickness of the cabinet body 1 at the right side of the heat removing channel 4 is 4-5 times of the wall thickness at the left side of the heat removing channel 4, so that the flowing liquid is not too close to the inner wall of the cabinet body 1, thereby effectively avoiding the condensation phenomenon of the hot air in the cabinet body 1 when encountering the inner wall of the cabinet body 1, effectively avoiding the damage of the electrical components in the cabinet body 1 due to, heat accuse forever ball 7 has been placed between end 31 and the end 32 that gathers heat, end 31 inner wall fixedly connected with that removes heat branch 6 of a plurality of evenly distributed, it communicates with each other with heat removal channel 4 to remove heat branch 6, it has heat conduction end 33 to gather end 32 inner wall fixedly connected with heat conduction end 33, the one end that removes heat branch 6 and heat conduction end 33 are close to each other all contacts with heat accuse forever ball 7, cabinet body 1, it makes to gather end 32 and heat conduction end 33 and heat conduction end, and the three heat conductivity improves gradually, thereby can produce certain heat conduction gradient difference between the three, make the partial heat of gathering at cabinet body 1 inner wall gather to heat conduction end 33 department gradually, and then enter into heat accuse forever ball 7 department, along with the slow rotation of heat accuse forever ball 7, thereby take away the heat of gathering to the cabinet body 1 outside guide by the mobile liquid gradually.

Referring to fig. 4, the heat removing support rod 6 includes a hollow tube 61 fixedly connected to the heat removing end 31 and a hollow micro-oblate spheroid connected to an end of the hollow tube 61, the hollow micro-oblate spheroid includes a shaping end 62 fixedly connected to the hollow tube 61 and a deformation end 63 embedded in a middle of an end of the shaping end 62 away from the hollow tube 61, when in use, flowing liquid enters the heat removing support rod 6 to deform the deformation end 63 to increase a contact area with the heat control permanent ball 7 and speed up the heat on the heat control permanent ball 7, the hollow tube 61 and the shaping end 62 are made of hard materials, the deformation end 63 is made of elastic materials, so that the deformation end 63 can adapt to the shape of the outer surface of the heat control permanent ball 7 to realize surface contact with the heat control permanent ball 7, thereby increasing the contact area and speed up the heat dissipation speed of the heat control permanent ball 7, the outer surface of the thermal control permanent ball 7, the outer surface of the deformation end 63 and the inner wall of the heat conducting end 33 are respectively coated with a SLIPS self-repairing super-smooth coating, and the SLIPS self-repairing super-smooth coatings enable the surfaces of the thermal control permanent ball 7, the deformation end 63 and the heat conducting end 33 to be super-smooth, so that the friction force between the thermal control permanent ball 7 and the deformation end 63 and between the thermal control permanent ball 33 is remarkably reduced, and the rotation of the thermal control permanent ball 7 is not.

Referring to fig. 5, a radial moving ball is connected inside the thermal control moving ball 7, the radial moving ball includes an inner connecting ball located at a central point, a plurality of thermal control moving rods 9 are fixedly connected to the outer end of the inner connecting ball, the thermal control moving rods 9 are fixedly connected to the outer end of the semi-hollow ball 10, and two adjacent semi-hollow balls 10 are in contact with each other, so that when the thermal control moving ball 7 is heated, the plurality of semi-hollow balls 10 are heated to enable the triggering moving balls 12 inside the semi-hollow balls to fall down and generate downward gravity impact, and therefore the stress density of the thermal control moving ball 7 is large, so that the thermal control moving ball 7 can be in a non-stop rotating state, and one end of the semi-hollow ball 10, which is far away from the inner connecting ball, is fixedly connected with the thermal control moving ball 7.

Referring to fig. 6, a ball containing cavity 11 is drilled at the joint of a hollow ball 10 and a thermal control rod 9, one end of the thermal control rod 9 close to the hollow ball 10 is of a hollow structure, the ball containing cavity 11 is communicated with the thermal control rod 9, a triggering moving ball 12 is placed in the hollow part of the thermal control rod 9, the hollow part of the thermal control rod 9 is made of an elastic material, after the thermal control rod 9 close to the heat collecting end 32 side and with the middle part facing downwards is heated, the thermal control rod 9 can expand along with the expansion of air in the ball containing cavity 11 due to the expansion of the thermal control rod 9 and the air in the ball containing cavity 11, the triggering moving ball 12 is in interference fit with the thermal control rod 9, the thermal control rod 9 is communicated with the ball containing cavity 11, when the thermal control rod 9 is not expanded, the triggering moving ball 12 can be in the thermal control rod 9, when the thermal control rod 9 expands, the triggering moving ball 12 falls into the ball containing cavity 11 from the thermal control rod 9, so as to generate downward gravity impact, and the thermal control, at this moment, the next thermal control moving rod 9 is close to the part entering the middle line downwards, the process also occurs, and the cabinet body 1 continuously operates, so that when heat is continuously generated, the thermal control permanent moving ball 7 can be effectively ensured to always have a certain clockwise rotation effect.

Can move ball 7's setting forever through the thermal control, under the effect that heat rose in cabinet body 1, imitate perpetual motion machine, make the forever ball 7 of thermal control move at cabinet body 1 continuously, continuously produce under the thermal condition, do not need artificial or machinery to add external force and can present certain clockwise pivoted state, thereby constantly guide the heat of cabinet body 1 to the outside, and taken away by flowing liquid, simultaneously at this in-process, not only carried out thermal giving off, move ball 7 through the thermal control forever simultaneously and rotate, still be a thermal process of consumptive, compare in prior art, show the thermal efficiency of giving off in the improvement cabinet body 1.

The above; but are merely preferred embodiments of the invention; the scope of the invention is not limited thereto; any person skilled in the art is within the technical scope of the present disclosure; the technical scheme and the improved concept of the invention are equally replaced or changed; are intended to be covered by the scope of the present invention.

Claims

1. The utility model provides a multi-functional large-scale server rack, includes rack body (1), rack body (1) back bottom is provided with radiating hole group (2), its characterized in that: the cabinet is characterized in that a plurality of active heat exchange balls (3) which are uniformly distributed are further embedded in the back of the cabinet body (1), each active heat exchange ball (3) comprises a heat removing end (31) and a heat collecting end (32), each heat removing end (31) is fixedly connected with each heat collecting end (32), each heat removing end (31) faces the outer side of the cabinet body (1), each heat collecting end (32) faces the inner side of the cabinet body (1), a water cooling channel is arranged inside the cabinet body (1), each water cooling channel comprises heat removing channels (4) chiseled in the cabinet body (1) and the heat removing ends (31), the heat removing channels (4) are communicated with each other, flowing liquid is filled in each water cooling channel, a circulating channel located outside the cabinet body (1) is connected between the two end parts of each water cooling channel, a condenser is installed on each circulating channel, and heat control permanent heat balls (7) are placed between the heat removing ends (31) and the heat collecting ends (32), the inner wall of the heat removing end (31) is fixedly connected with a plurality of uniformly distributed heat removing support rods (6), the heat removing support rods (6) are communicated with the heat removing channel (4), the inner wall of the heat collecting end (32) is fixedly connected with a heat conducting end (33), and one ends, close to each other, of the heat removing support rods (6) and the heat conducting end (33) are both contacted with the heat control permanent ball (7).

2. A multifunctional large server cabinet according to claim 1, wherein: the heat removal channel (4) in the cabinet body (1) is located on one side of the center line outside the cabinet body (1), and the wall thickness of the cabinet body (1) on the right side of the heat removal channel (4) is 4-5 times that of the wall thickness of the left side of the heat removal channel (4).

3. A multifunctional large server cabinet according to claim 2, wherein: the cabinet body (1), the heat collecting end (32) and the heat conducting end (33) are all made of heat conducting materials, and the heat conductivities of the cabinet body, the heat collecting end and the heat conducting end are gradually improved.

4. A multifunctional large server cabinet according to claim 1, wherein: the heat removing support rod (6) comprises a hollow tube (61) fixedly connected with the heat removing end (31) and a hollow micro flat ball connected to the end of the hollow tube (61).

5. A multifunctional large-scale server cabinet according to claim 4, characterized in that: the hollow micro flat ball comprises a shaping end (62) fixedly connected with the hollow pipe (61) and a deformation end (63) embedded in the middle of one end, far away from the hollow pipe (61), of the shaping end (62).

6. A multifunctional large-scale server cabinet according to claim 5, characterized in that: the hollow pipe (61) and the shaping end (62) are both made of hard materials, and the deformation end (63) is made of elastic materials.

7. A multifunctional large server cabinet according to claim 6, wherein: and SLIPS self-repairing super-smooth coatings are respectively coated on the outer surface of the thermal control permanent ball (7), the outer surface of the deformation end (63) and the inner wall of the heat conducting end (33).

8. A multifunctional large server cabinet according to claim 1, wherein: ball (7) internal connection has the radiation to move forever is moved in thermal control, the radiation moves the ball including the in-connection ball that is located the central point, a plurality of evenly distributed's of in-connection ball outer end fixedly connected with hot control moves pole (9), hot control moves pole (9) outer end fixedly connected with half clean shot (10), adjacent two half clean shot (10) contact each other, and half clean shot (10) keep away from the one end and the hot control of in-connection ball forever move ball (7) fixed connection.

9. A multifunctional large server cabinet according to claim 8, wherein: the connecting part of the semi-hollow ball (10) and the thermal control moving rod (9) is provided with a ball containing cavity (11), one end, close to the semi-hollow ball (10), of the thermal control moving rod (9) is of a hollow structure, the ball containing cavity (11) is communicated with the thermal control moving rod (9), and a trigger moving ball (12) is placed in the hollow part of the thermal control moving rod (9).

10. A multifunctional large server cabinet according to claim 9, wherein: the hollow part of the thermal control moving rod (9) is made of elastic material, the triggering moving ball (12) is in interference fit with the thermal control moving rod (9), and the thermal control moving rod (9) is communicated with the ball containing cavity (11).