CN112346549A - Computer heat abstractor is used in software development - Google Patents

Abstract

The invention relates to the technical field of heat dissipation devices, and discloses a computer heat dissipation device for software development, which comprises a box body, wherein the top surface of the box body is provided with a first mounting groove, the top surface of an inner cavity of the box body is fixedly connected with a mounting sleeve, the inner side of the mounting sleeve is provided with a fan, the inner surface of the first mounting groove is movably sleeved with a lantern ring, the inner surface of the lantern ring is fixedly sleeved with a filter screen, and the top surface of the lantern ring is fixedly connected with a limiting ring. This computer heat abstractor for software development, through the top surface fixed connection mount at the box to at the medial surface activity joint fly leaf of mount, cup joint the lantern ring that will be connected with the spacing ring in the mounting groove No. one, and make lantern ring internal surface connect the filter screen, realize during the slip fly leaf that the fly leaf is fixed to the extrusion of inner ring in the jurisdiction, and utilize magnetic sheet and fly leaf magnetic adsorption, when needing to dismantle the slip fly leaf break away from the magnetic sheet can, it is convenient to install, dismantle rapidly, excellent in use effect.

Description

Computer heat abstractor is used in software development

Technical Field

The invention relates to the technical field of heat dissipation devices, in particular to a computer heat dissipation device for software development.

Background

The computer is commonly called computer, and is a modern electronic computing machine for high-speed computation, which can perform numerical computation, logic computation and memory function. The computer is a modern intelligent electronic device which can run according to a program and automatically process mass data at a high speed, and consists of a hardware system and a software system, and a computer without any software is called a bare computer. The computer can be divided into five types, namely a super computer, an industrial control computer, a network computer, a personal computer and an embedded computer, more advanced computers comprise a biological computer, a photon computer, a quantum computer and the like, and a computer inventor is John Von Neumann. The computer is one of the most advanced scientific and technical inventions in the 20 th century, has extremely important influence on the production activities and social activities of human beings, and develops rapidly with strong vitality. The application field of the system is expanded from the initial military scientific research application to various fields of society, a large-scale computer industry is formed, and the technology progress in the global range is driven, so that the profound social change is initiated, computers are spread throughout general schools, enterprises and public institutions, enter common people and become necessary tools in the information society, in the using process of the computers, software development is frequently needed, a software system or a software part in the system is built according to the requirements of users, the software development is a system engineering comprising requirement capturing, requirement analysis, design, realization and testing, and the software is generally realized by using a certain programming language. Development is typically possible using software development tools. The software is divided into system software and application software, and not only includes programs which can run on a computer, but also files related to the programs are generally considered to be part of the software, and the general processes of software design ideas and methods include algorithms and methods for designing functions and implementation of the software, overall structural design and module design of the software, programming and debugging, program joint debugging and testing, and writing and submitting the programs.

Present software development uses computer heat abstractor, in the use, because computer host computer internally mounted has a large amount of components, produces a large amount of heats and need dispel the heat at the operation in-process, add the filter screen usually in order to prevent that the dust from getting into, nevertheless filter and appear blockking up after filtering many times, and influence the intake after blockking up, reduce the radiating efficiency of cooling, it is comparatively troublesome to dismantle clean filter screen, needs the instrument supplementary, and the result of use is not good.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides the computer heat dissipation device for software development, which has the advantage of being convenient for cleaning filtered dust and solves the problems in the background art.

The invention provides the following technical scheme: the utility model provides a computer heat abstractor for software development, the power distribution box comprises a box body, a mounting groove has been seted up to the top surface of box, the top surface fixedly connected with installation cover of internal chamber of box, the fan is installed to the inboard of installation cover, the internal surface activity of a mounting groove has cup jointed the lantern ring, the internal surface fixed sleeving of the lantern ring has connect the filter screen, the top surface fixedly connected with spacing ring of the lantern ring, the fixed frame of top surface fixedly connected with of box, the medial surface activity joint of fixed frame has the fly leaf, the air inlet duct has been seted up to the top surface of fly leaf.

Preferably, the inner side surface of the fixing frame is provided with a sliding groove, the side surface of the movable plate is fixedly connected with a sliding plate, and the inner surface of the sliding groove is movably clamped with the sliding plate.

Preferably, the right side fixedly connected with magnetic sheet of fixed frame internal surface, magnetic sheet and spout fixed joint.

Preferably, the top surface of filter screen is equipped with the sponge ring, the internal diameter of air inlet duct is less than the external diameter of sponge ring.

Preferably, a threaded hole is formed in the side face of the box body, a cover plate is arranged on the side face of the box body, a bolt is movably sleeved on the side face of the cover plate, and the bolt penetrates through the cover plate and is in threaded sleeve connection with the threaded hole.

Preferably, the bottom surface of the box body is provided with a second mounting groove, and the inner surface of the second mounting groove is fixedly sleeved with a filter sleeve.

Preferably, the inner side surface of the cover plate is fixedly connected with a fixed rod, the outer surface of the fixed rod is movably sleeved with a mounting plate, the side surface of the mounting plate is fixedly connected with a leather bag, the top surface thread of the leather bag is sleeved with a sealing plug, and the outer surface thread of the fixed rod is sleeved with a locking cap.

Preferably, it is characterized in that: the computer heat dissipation device for software development further comprises a cooling device;

the cooling device is arranged in the inner cavity of the box body;

a sliding rail is arranged on the inner wall of the box body;

the starting end of the sliding rail is fixedly connected to the left part of the inner cavity of the box body, and the terminating end of the sliding rail is fixedly connected to the right part of the inner cavity of the box body;

the sliding rail is connected with a roller in a sliding manner, and the roller is rotationally connected to the supporting frame;

a support table is fixed above the support frame;

the air pumps are fixedly connected above the supporting table, and the number of the air pumps is two, and the two air pumps are respectively connected to the air valve discs through symmetrical connecting components;

the connecting assembly includes: the device comprises a first gas pipe, a gas distribution box, a take-up pulley, a spring, a first support spring, a second gas pipe, a third gas pipe, a first butt joint pipe and a second butt joint pipe;

the output end of the air pump is fixedly connected with the first air conveying pipe, and the input end of the air pump is connected with a cooling air source;

the output end of the first gas pipe is fixedly connected with the gas inlet end of the gas distribution box;

a take-up pulley is rotatably connected at the center of the inside of the gas distribution box;

a spring is wound on the take-up pulley;

a second gas pipe and a third gas pipe are respectively connected to the upper part and the lower part of the gas distribution box, and the second gas pipe and the third gas pipe respectively penetrate through the upper end and the lower end of the gas distribution box;

one end of the clockwork spring is fixedly connected to the second gas pipe;

the other end of the clockwork spring is fixedly connected to a third gas pipe;

the second air pipe and the third air pipe respectively penetrate through the first supporting spring and the second supporting spring;

one end of the first support spring and one end of the second support spring are respectively fixedly connected to the upper end and the lower end of the outer part of the air distribution box and are matched with the connecting positions of the second air conveying pipe and the third air conveying pipe;

the other end ends of the first supporting spring and the second supporting spring are respectively and fixedly connected with a first butt joint pipe and a second butt joint pipe;

the first butt joint pipe and the second butt joint pipe are fixedly connected to the air valve disc;

the first butt joint pipe and the second butt joint pipe penetrate through the air valve disc and are fixedly connected in a first arc-shaped air valve cavity;

the first arc-shaped air valve cavity is arranged in a left inner cavity of the air valve disc;

a second arc-shaped gas valve cavity is arranged at a position symmetrical to the first arc-shaped gas valve cavity;

a first arc-shaped sliding rail is arranged inside the first arc-shaped gas valve cavity;

a second arc-shaped sliding rail is arranged inside the second arc-shaped gas valve cavity;

the first arc-shaped sliding rail is connected with a first sliding block in a sliding manner;

the second arc-shaped sliding rail is connected with a second sliding block in a sliding manner;

the first sliding block is fixedly connected with a first connecting cavity;

a second connecting cavity is fixedly connected to the second sliding block;

the first connecting cavity and the second connecting cavity are respectively installed at the left end and the right end of the gas transmission cavity in a sliding mode, and one end of the first connecting cavity and one end of the second connecting cavity penetrate through the gas transmission cavity;

the first connecting cavity and the second connecting cavity are fixedly arranged on the left outer wall and the right outer wall of the piston respectively;

the piston is connected inside the air conveying cavity in a sliding mode;

a first air spring and a second air spring are fixedly connected between the first connecting cavity and the piston and between the second connecting cavity and the piston respectively;

one end of each of the first air spring and the second air spring is fixed on the outer part of the piston, the other end of each of the first air spring and the second air spring is fixedly connected to the inner wall of the air conveying cavity, and the first connecting cavity and the second connecting cavity respectively penetrate through the first air spring and the second air spring;

the piston is communicated with the gas transmission cavity, and a fourth gas transmission pipe communicated with the piston is fixedly connected to the center of the piston.

Preferably, the case includes: the outer box body and the inner box body are arranged on the inner side of the outer box body, a cooling pipe is wound on the outer surface of the inner box body, and a water inlet of the cooling pipe is connected with a cooling water source through a micro water pump;

the server heat dissipation device for software development further comprises a first temperature sensor, a second temperature sensor, a flow velocity sensor, a controller and an alarm;

the first temperature sensor is used for detecting the surface temperature of the cooling pipe;

the second temperature sensor is used for detecting the surface temperature of the outer box body;

the flow velocity sensor is used for detecting the flow velocity of the liquid output by the micro water pump;

the controller stores theoretical unit length heat loss of the cooling pipe and heat exchange coefficient of the theoretical cooling pipe;

the controller is electrically connected with the first temperature sensor, the second temperature sensor, the flow rate sensor and the alarm;

the controller is based on first temperature sensor, second temperature sensor, flow rate sensor control alarm report to the police, includes:

calculating the heat loss of the cooling pipe per unit length through a formula based on the surface temperature of the cooling pipe detected by the first temperature sensor, the surface temperature of the outer box detected by the second temperature sensor and the flow rate of the liquid output by the micro water pump detected by the flow rate sensor;

heat loss per unit length of the cooling tube;

in the formula, s₁The heat transfer coefficient of the cooling pipe is shown,pi is the circumference ratio, and is 3.14, d is the inner diameter of the cooling pipe, and s₂Denotes the heat transfer coefficient of the case, b denotes the average distance between the outer case and the inner case, λ denotes the heat conductivity of the cooling pipe, T₂Represents an average value, T, of values detected by the second temperature sensor during a target time₁Represents an average value of values detected by the first temperature sensor over a target time,

the order of the bottom is 2,

the logarithm of (d); e is a constant, the value is 2.72, K is the average error coefficient of the first temperature sensor and the second temperature sensor, and eta is the surface cleaning coefficient of the cooling pipe;

calculating the actual heat exchange coefficient of the cooling pipe based on the flow speed of the liquid output by the micro water pump and a formula, which are detected by the flow speed sensor;

the actual heat exchange coefficient r of the cooling pipe;

in the formula, q is the heat loss of the cooling pipe in theoretical unit length, v is the average value of the detection values of the flow velocity sensor in the target time, and n is the kinematic viscosity of the liquid output by the micro water pump;

and when the calculated actual heat exchange coefficient of the cooling pipe is smaller than the heat exchange coefficient of the theoretical cooling pipe stored in the controller, the controller triggers an alarm device to give an alarm.

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

1. this computer heat abstractor for software development, through the top surface fixed connection mount at the box to at the medial surface activity joint fly leaf of mount, cup joint the lantern ring that will be connected with the spacing ring in the mounting groove No. one, and make lantern ring internal surface connect the filter screen, realize during the slip fly leaf that the fly leaf is fixed to the extrusion of inner ring in the jurisdiction, and utilize magnetic sheet and fly leaf magnetic adsorption, when needing to dismantle the slip fly leaf break away from the magnetic sheet can, it is convenient to install, dismantle rapidly, excellent in use effect.

2. This computer heat abstractor is used in software development cup joints in the mounting groove through making the lantern ring that is connected with the filter screen to utilize fly leaf extrusion limiting plate to realize fixing, roll-off fly leaf and take out the lantern ring when needing to clear up the filter screen plug, can clean, it is clean convenient, labour saving and time saving has guaranteed the clearance effect, has reduced the clearance degree of difficulty, ensures that the follow-up radiating effect of box is good, excellent in use effect.

3. This computer heat abstractor is used in software development has the mounting panel through the medial surface swing joint at the apron to make the front of installation set up the leather bag, through filling into cold water in to the leather bag, under the inside unusual circumstances of heaing up of box, receive the big influence of water specific heat capacity, absorb the aquatic in the leather bag with a large amount of heats in the box inside rapidly, avoid the heat dissipation untimely that the box overheated leads to the fact unusually, improve chip working property.

4. This computer heat abstractor is used in software development, medial surface swing joint through the apron has the mounting panel to make the front of installation set up the leather bag, through filling cold water into to the leather bag, under the inside great condition that heaies up of box, receive the big influence of water specific heat capacity, the heat flow direction leather bag department of the higher department of temperature in the box changes the inside temperature distribution of box, make the mounting panel be located the apron inboard and be close to No. two mounting grooves departments, the heat of being convenient for in time spills, excellent in use effect.

Drawings

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

FIG. 2 is a bottom view of the structure of the present invention;

FIG. 3 is an enlarged view of the structure at A in FIG. 2;

FIG. 4 is an exploded view of the structural collar of the present invention;

FIG. 5 is a cross-sectional view of a structural box of the present invention;

FIG. 6 is a schematic view of the inside of a structural cover plate of the present invention;

FIG. 7 is a left side view of the cooling device of the present invention;

FIG. 8 is a top view of a cooling device in accordance with the present invention.

In the figure: 1. a box body; 2. a first mounting groove; 3. installing a sleeve; 4. a fan; 5. a collar; 6. a filter screen; 7. a limiting ring; 8. a fixing frame; 9. a movable plate; 10. an air inlet groove; 11. a chute; 12. a slide plate; 13. a magnetic plate; 14. a sponge ring; 15. mounting grooves II; 16. a filter sleeve; 17. a cover plate; 18. a threaded hole; 19. a bolt; 20. fixing the rod; 21. mounting a plate; 22. a locking cap; 23. a skin pocket; 24. a sealing plug; 25. a gas distribution box; 26. a take-up pulley; 27. a third gas delivery pipe; 28. a first support spring; 29. a second support spring; 30. a first docking pipe; 31. a second pair of adapter tubes; 32. an air valve disc; 33. an arc-shaped air valve cavity; 34. a second arc-shaped gas valve cavity; 35. an arc-shaped slide rail; 36. a second arc-shaped slide rail; 37. a slider; 38. a second slider; 39. a first connection chamber; 40. a second connection chamber; 41. an air delivery cavity; 42. a piston; 43. a first air spring; 44. a second air spring; 45. a fourth gas delivery pipe; 46. a second gas delivery pipe; 47. a slide rail; 48. a clockwork spring; 49. a roller; 50. a support frame; 51. a support table; 52. an air pump; 53. a first gas delivery conduit.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-6, a computer heat dissipation device for software development comprises a box body 1, a first mounting groove 2 is formed in the top surface of the box body 1, a mounting sleeve 3 is fixedly connected to the top surface of an inner cavity of the box body 1, a fan 4 is installed on the inner side of the mounting sleeve 3, a lantern ring 5 is movably sleeved on the inner surface of the first mounting groove 2, a filter screen 6 is fixedly sleeved on the inner surface of the lantern ring 5, a limiting ring 7 is fixedly connected to the top surface of the lantern ring 5, a fixing frame 8 is fixedly connected to the top surface of the box body 1, a movable clamping plate 9 is movably clamped on the inner side surface of the fixing frame 8.

The inner side surface of the fixed frame 8 is provided with a sliding groove 11, the side surface of the movable plate 9 is fixedly connected with a sliding plate 12, the inner surface of the sliding groove 11 is movably clamped with the sliding plate 12, and the movable clamping of the sliding groove 11 and the sliding plate 12 is utilized to enable the movable plate 9 to have a stable sliding effect.

Wherein, the right side of the internal surface of the fixed frame 8 is fixedly connected with a magnetic plate 13, the magnetic plate 13 is fixedly clamped with the chute 11, and the magnetic plate 13 is adsorbed with the movable plate 9 to realize the relative fixation of the movable plate 9.

Wherein, the top surface of filter screen 6 is equipped with sponge ring 14, and the internal diameter of air inlet groove 10 is less than the external diameter of sponge ring 14, utilizes sponge ring 14 to realize the dehumidification of moisture in the air, absorbs the moisture in the air.

Wherein, threaded hole 18 is seted up to the side of box 1, and the side of box 1 is equipped with apron 17, and the side activity of apron 17 has cup jointed bolt 19, and bolt 19 passes apron 17 and cup joints with threaded hole 18 screw thread, and the screw thread that utilizes bolt 19 and threaded hole 18 cup joints, realizes the fixed mounting of apron 17.

Wherein, No. two mounting grooves 15 have been seted up to the bottom surface of box 1, and No. two internal surface fixing of mounting groove 15 has cup jointed filter sleeve 16, and No. two mounting grooves 15 are used for getting rid of the air, realize the air current.

Wherein, the medial surface fixedly connected with dead lever 20 of apron 17, the surface activity of dead lever 20 has cup jointed mounting panel 21, the side fixedly connected with leather bag 23 of mounting panel 21, the sealing plug 24 has been cup jointed to the top surface screw thread of leather bag 23, the surface screw thread of dead lever 20 has cup jointed locking cap 22, utilizes the cold water in the leather bag 23 to realize the dilution of high temperature department in the box 1, the concentrated heat in the even box 1.

The working principle is as follows: when the temperature in the box body 1 rises, part of heat moves downwards and is absorbed into liquid in the leather bag, the whole temperature in the box body 1 is reduced, when heat dissipation is carried out, external air enters through the air inlet groove 10 on the top surface of the movable plate 9, dust and impurities in the air are filtered on the top surface of the filter screen 6, pure air enters into the box body 1 through the filter screen 6, moisture in the air is absorbed into the sponge ring 14 at the sponge ring 14, the external air enters into the box body 1 for heat exchange, the temperature in the box body 1 is gradually reduced, and the cooled air is blown downwards through the filter sleeve 16 at the second mounting groove 15; when the filter screen 6 needs to be cleaned, the movable plate 9 is slid to separate the movable plate 9 from the magnetic plate 13, the movable plate 9 is slid to the left side of the first mounting groove 2, the lantern ring 5 is upwards taken out, the filter screen 6 in the lantern ring 5 is taken out, and the filter screen is cleaned.

Wherein, its characterized in that: the computer heat dissipation device for software development further comprises a cooling device;

the cooling device is arranged in the inner cavity of the box body 1;

a slide rail 47 is arranged on the inner wall of the box body 1;

the starting end of the slide rail 47 is fixedly connected to the left part of the inner cavity of the box body 1, and the terminating end of the slide rail 47 is fixedly connected to the right part of the inner cavity of the box body 1;

the slide rail 47 is connected with a roller 49 in a sliding manner, and the roller 49 is rotationally connected to a support frame 50;

a support platform 51 is fixed above the support frame 50;

air pumps 52 are fixedly connected above the support platform 51, and the number of the air pumps 52 is two, and the two air pumps are respectively connected to the air valve disc 32 through symmetrical connecting components;

the connecting assembly includes: the air supply device comprises a first air supply pipe 53, an air distribution box 25, a take-up pulley 26, a clockwork spring 48, a first support spring 28, a second support spring 29, a second air supply pipe 46, a third air supply pipe 27, a first butt joint pipe 30 and a second butt joint pipe 31;

the output end of the air pump 52 is fixedly connected with the first air pipe 53, and the input end of the air pump 52 is connected with a cooling air source;

the output end of the first air conveying pipe 53 is fixedly connected with the air inlet end of the air distribution box 25;

a take-up pulley 26 is rotatably connected to the center of the interior of the gas distribution box 25;

a spring 48 is wound on the take-up pulley 26;

the upper part and the lower part of the air distribution box 25 are respectively connected with a second air conveying pipe 46 and a third air conveying pipe 27, and the second air conveying pipe 46 and the third air conveying pipe 27 respectively penetrate through the upper end and the lower end of the air distribution box 25;

one end of the spiral spring 48 is fixedly connected to the second air conveying pipe 46;

the other end of the spring 48 is fixedly connected to the third air pipe 27;

the second air delivery pipe 46 and the third air delivery pipe 27 respectively penetrate through the first supporting spring 28 and the second supporting spring 29;

one end of the first supporting spring 28 and one end of the second supporting spring 29 are respectively and fixedly connected with the upper end and the lower end of the outer part of the air distribution box 25 and are matched with the connecting positions of the second air pipe 46 and the third air pipe 27;

the other end ends of the first supporting spring 28 and the second supporting spring 29 are fixedly connected with a first connecting pipe pair 30 and a second connecting pipe pair 31 respectively;

the first connecting pipe pair 30 and the second connecting pipe pair 31 are fixedly connected to an air valve disc 32;

the first butt joint pipe 30 and the second butt joint pipe 31 penetrate through the air valve disc 32 and are fixedly connected in a first arc-shaped air valve cavity 33;

the first arc-shaped air valve cavity 33 is arranged in the left inner cavity of the air valve disk 32;

a second arc-shaped gas valve cavity 34 is arranged at a position symmetrical to the first arc-shaped gas valve cavity 33;

a first arc-shaped slide rail 35 is arranged in the first arc-shaped gas valve cavity 33;

a second arc-shaped slide rail 36 is arranged in the second arc-shaped air valve cavity 34;

the first arc-shaped slide rail 35 is connected with a first slide block 37 in a sliding manner;

a second sliding block 38 is connected to the second arc-shaped sliding rail 36 in a sliding manner;

a first connecting cavity 39 is fixedly connected to the first sliding block 37;

a second connecting cavity 40 is fixedly connected to the second sliding block 38;

the first connecting cavity 39 and the second connecting cavity 40 are respectively slidably mounted at the left end and the right end of an air transmission cavity 41, and one end of the first connecting cavity 39 and one end of the second connecting cavity 40 penetrate through the air transmission cavity 41;

the first connection cavity 39 and the second connection cavity 40 are respectively and fixedly installed on the left and right outer walls of the piston 42;

the piston 42 is connected inside the air conveying cavity 41 in a sliding mode;

a first air spring 43 and a second air spring 44 are fixedly connected between the first connecting cavity 39 and the second connecting cavity 40 and the piston 42 respectively;

the first air spring 43 and the second air spring 44 have one end fixed on the outside of the piston 42 and the other end fixed on the inner wall of the air delivery chamber 41, and the first connection chamber 39 and the second connection chamber 40 respectively penetrate through the first air spring 43 and the second air spring 44;

the piston 42 is communicated with the air conveying cavity 41, and a fourth air conveying pipe 45 communicated with the piston 42 is fixedly connected to the center of the piston 42.

The technical scheme has the beneficial effects that: air flowing out of the air pump is respectively conveyed into the first butt joint pipe and the second butt joint pipe through the air distribution box, then the air in the first butt joint pipe and the second butt joint pipe is collected into the arc-shaped air valve cavity, the air in the arc-shaped air valve cavity flows into the arc-shaped slide rail and then enters the air conveying cavity through the connecting cavity, the air collected in the air conveying cavity from the first arc-shaped cavity and the second arc-shaped cavity is conveyed to the fourth air conveying pipe, and the air output from the fourth air conveying pipe is used for cooling the server body; in the structure, the gas distribution box can distribute the gas in a single direction output from the air pump to an upper direction and a lower direction, the spiral spring and the take-up pulley are arranged in the gas distribution box, so that the positions of the second gas pipe and the third gas pipe can be adjusted by taking up and paying off, when the positions of the second gas pipe and the third gas pipe swing up and down, the positions of the first butt joint pipe and the second butt joint pipe can swing up and down, at the moment, the first support spring and the second support spring can play a role in damping the system, the risk of rapid impact is avoided, when the pressures and the sizes of the gas conveyed by the second gas pipe and the third gas pipe are different, the pressures and the sizes of the gas entering the arc-shaped gas valve cavity are different, at the moment, the slide block slides along the arc-shaped slide rail from a high-pressure direction to a low-pressure direction, so that the position of the gas conveying cavity can be changed, at the moment, the first connecting cavity and the second connecting cavity move along with the movement of the sliding block in the vertical direction, when the pressure of the air transmission cavities arranged on the left and the right is different, the connecting cavities move from the high-pressure end to the low-pressure end, and therefore the position of the air transmission cavities in the horizontal direction is adjusted.

Wherein, the box 1 includes: the outer box body and the inner box body are arranged on the inner side of the outer box body, a cooling pipe is wound on the outer surface of the inner box body, and a water inlet of the cooling pipe is connected with a cooling water source through a micro water pump;

the server heat dissipation device for software development further comprises a first temperature sensor, a second temperature sensor, a flow velocity sensor, a controller and an alarm;

the first temperature sensor is used for detecting the surface temperature of the cooling pipe;

the second temperature sensor is used for detecting the surface temperature of the outer box body;

the flow velocity sensor is used for detecting the flow velocity of the liquid output by the micro water pump;

the controller stores theoretical unit length heat loss of the cooling pipe and heat exchange coefficient of the theoretical cooling pipe;

the controller is electrically connected with the first temperature sensor, the second temperature sensor, the flow rate sensor and the alarm;

the controller is based on first temperature sensor, second temperature sensor, flow rate sensor control alarm report to the police, includes:

calculating the heat loss of the cooling pipe per unit length through a formula (1) based on the surface temperature of the cooling pipe detected by the first temperature sensor, the surface temperature of the outer box detected by the second temperature sensor and the flow rate of the liquid output by the micro water pump detected by the flow rate sensor;

heat loss per unit length of the cooling pipe 13;

in formula 1, s₁The heat transfer coefficient of the cooling pipe is shown, wherein pi is the circumference ratio and takes a value of 3.14, d is the inner diameter of the cooling pipe, and s₂Denotes the heat transfer coefficient of the case, b denotes the average distance between the outer case and the inner case, λ denotes the heat conductivity of the cooling pipe, T₂Represents an average value, T, of values detected by the second temperature sensor during a target time₁Represents an average value of values detected by the first temperature sensor over a target time,

the order of the bottom is 2,

the logarithm of (d); e is a constant, the value is 2.72, K is the average error coefficient of the first temperature sensor and the second temperature sensor, and eta is the surface cleaning coefficient of the cooling pipe (the value is more than 0.5 and less than or equal to 1, the cleaner the surface, the larger the cleaning coefficient);

calculating the actual heat exchange coefficient of the cooling pipe based on the flow speed of the liquid output by the micro water pump detected by the flow speed sensor and a formula (2);

the actual heat exchange coefficient r of the cooling pipe;

in formula 2, q is the theoretical heat loss per unit length of the cooling pipe, v is the average value of the detection values of the flow rate sensor in the target time, and n is the kinematic viscosity of the liquid output by the micro-water pump 10;

and when the calculated actual heat exchange coefficient of the cooling pipe is smaller than the heat exchange coefficient of the theoretical cooling pipe stored in the controller, the controller triggers an alarm device to give an alarm.

The technical scheme has the beneficial effects that: the server heat dissipation device for software development further comprises a first temperature sensor, a second temperature sensor, a speed detection device flow velocity sensor, a controller and an alarm; the first temperature sensor is used for detecting the surface temperature of the cooling pipe; the second temperature sensor is used for detecting the surface temperature of the box body 1; the flow rate sensor is used for detecting the flow rate of liquid flowing out of the micro water pump; the controller stores theoretical unit length heat loss of the cooling pipe and heat exchange coefficient of the theoretical cooling pipe; the controller is electrically connected with the first temperature sensor, the second temperature sensor, the flow rate sensor and the alarm; the controller controls an alarm to give an alarm based on the first temperature sensor, the second temperature sensor and the flow rate sensor.

Calculating the heat loss per unit length of the cooling pipe based on the surface temperature of the cooling pipe detected by the first temperature sensor, the surface temperature of the box body 1 detected by the second temperature sensor and the flow rate of the liquid flowing out of the micro water pump detected by the flow rate sensor by using a formula (1); calculating the actual heat exchange coefficient of the cooling pipe based on the flow velocity of the liquid flowing out of the micro water pump detected by the flow velocity sensor and a formula (2);

the heat loss of the cooling pipe in unit length and the heat transfer coefficient of the cooling pipe, the inner diameter of the cooling pipe, the heat transfer coefficient of the box body, the average distance between the outer box body and the inner box body of the box body, the heat conduction coefficient of the cooling pipe, the average value of the detection value of the second temperature sensor in the target time, the average value of the detection value of the first temperature sensor in the target time, the average error coefficient of the first temperature sensor and the second temperature sensor, the surface cleaning coefficient of the cooling pipe are related, the heat exchange coefficient of the cooling pipe is related to the heat loss of the cooling pipe in the theoretical unit length, the average value of the detection value of the flow rate sensor in the target time is related to the kinematic viscosity of the liquid flowing out of the micro water pump, and the calculation result is more reliable.

And when the calculated heat exchange coefficient of the cooling pipe is smaller than the heat exchange coefficient of the theoretical cooling pipe stored in the controller, the controller triggers the alarm device.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (9)

1. The utility model provides a computer heat abstractor for software development, includes box (1), its characterized in that: mounting groove (2) have been seted up to the top surface of box (1), top surface fixedly connected with installation cover (3) of box (1) inner chamber, fan (4) are installed to the inboard of installation cover (3), lantern ring (5) have been cup jointed in the internal surface activity of mounting groove (2), filter screen (6) have been cup jointed to the internal surface fixation of the lantern ring (5), top surface fixedly connected with spacing ring (7) of the lantern ring (5), the fixed frame (8) of top surface fixedly connected with of box (1), the medial surface activity joint of fixed frame (8) has fly leaf (9), air inlet duct (10) have been seted up to the top surface of fly leaf (9).

2. The heat dissipating device for a software development computer according to claim 1, wherein: the inner side surface of the fixed frame (8) is provided with a sliding groove (11), the side surface of the movable plate (9) is fixedly connected with a sliding plate (12), and the inner surface of the sliding groove (11) is movably clamped with the sliding plate (12).

3. The heat dissipating device for a software development computer according to claim 2, wherein: the right side fixedly connected with magnetic sheet (13) of fixed frame (8) internal surface, magnetic sheet (13) and spout (11) fixed joint.

4. The heat dissipating device for a software development computer according to claim 1, wherein: the top surface of filter screen (6) is equipped with sponge ring (14), the internal diameter of air inlet groove (10) is less than the external diameter of sponge ring (14).

5. The heat dissipating device for a software development computer according to claim 1, wherein: threaded holes (18) are formed in the side face of the box body (1), a cover plate (17) is arranged on the side face of the box body (1), bolts (19) are movably sleeved on the side face of the cover plate (17), and the bolts (19) penetrate through the cover plate (19) and are in threaded sleeve connection with the threaded holes (18).

6. The heat dissipating device for a software development computer according to claim 5, wherein: no. two mounting grooves (15) are formed in the bottom surface of the box body (1), and a filter sleeve (16) is fixedly sleeved on the inner surface of each mounting groove (15).

7. The heat dissipating device for a software development computer according to claim 5, wherein: the utility model discloses a safety belt cover, including apron (17), medial surface fixedly connected with dead lever (20) of apron (17), mounting panel (21) have been cup jointed in the surface activity of dead lever (20), the side fixedly connected with leather bag (23) of mounting panel (21), sealing plug (24) have been cup jointed to the top surface screw thread of leather bag (23), the surface screw thread of dead lever (20) has cup jointed locking cap (22).

8. The heat dissipating device for a software development computer according to claim 1, wherein: the computer heat dissipation device for software development further comprises a cooling device;

the cooling device is arranged in the inner cavity of the box body (1);

a slide rail (47) is arranged on the inner wall of the box body (1);

the starting end of the sliding rail (47) is fixedly connected to the left part of the inner cavity of the box body (1), and the terminating end of the sliding rail (47) is fixedly connected to the right part of the inner cavity of the box body (1);

the sliding rail (47) is connected with a roller (49) in a sliding manner, and the roller (49) is rotationally connected to the supporting frame (50);

a support table (51) is fixed above the support frame (50);

air pumps (52) are fixedly connected above the supporting platform (51), and the number of the air pumps (52) is two, and the two air pumps are respectively connected to the air valve disc (32) through symmetrical connecting components;

the connecting assembly includes: the air delivery device comprises a first air delivery pipe (53), an air distribution box (25), a take-up pulley (26), a spiral spring (48), a first support spring (28), a second support spring (29), a second air delivery pipe (46), a third air delivery pipe (27), a first butt joint pipe (30) and a second butt joint pipe (31);

the output end of the air pump (52) is fixedly connected with the first air conveying pipe (53), and the input end of the air pump (52) is connected with a cooling air source;

the output end of the first air conveying pipe (53) is fixedly connected with the air inlet end of the air distribution box (25);

a take-up pulley (26) is rotatably connected to the center of the interior of the gas distribution box (25);

a spring (48) is wound on the take-up pulley (26);

a second air conveying pipe (46) and a third air conveying pipe (27) are respectively connected to the upper side and the lower side of the air distribution box (25), and the second air conveying pipe (46) and the third air conveying pipe (27) respectively penetrate through the upper end and the lower end of the air distribution box (25);

one end of the clockwork spring (48) is fixedly connected to the second air conveying pipe (46);

the other end of the clockwork spring (48) is fixedly connected to the third air conveying pipe (27);

the second air conveying pipe (46) and the third air conveying pipe (27) respectively penetrate through the first supporting spring (28) and the second supporting spring (29);

one end of the first supporting spring (28) and one end of the second supporting spring (29) are respectively and fixedly connected with the upper end and the lower end of the outer part of the air distribution box (25) and are matched with the connecting positions of the second air conveying pipe (46) and the third air conveying pipe (27);

the other end ends of the first supporting spring (28) and the second supporting spring (29) are respectively and fixedly connected with a first butt joint pipe (30) and a second butt joint pipe (31);

the first butt joint pipe (30) and the second butt joint pipe (31) are fixedly connected to an air valve disc (32);

the first butt joint pipe (30) and the second butt joint pipe (31) penetrate through the air valve disc (32) and are fixedly connected in a first arc-shaped air valve cavity (33);

the first arc-shaped air valve cavity (33) is arranged in a left inner cavity of the air valve disc (32);

a second arc-shaped gas valve cavity (34) is arranged at a position symmetrical to the first arc-shaped gas valve cavity (33);

a first arc-shaped sliding rail (35) is arranged in the first arc-shaped gas valve cavity (33);

a second arc-shaped sliding rail (36) is arranged in the second arc-shaped gas valve cavity (34);

the first arc-shaped sliding rail (35) is connected with a first sliding block (37) in a sliding manner;

a second sliding block (38) is connected on the second arc-shaped sliding rail (36) in a sliding way;

a first connecting cavity (39) is fixedly connected to the first sliding block (37);

a second connecting cavity (40) is fixedly connected to the second sliding block (38);

the first connecting cavity (39) and the second connecting cavity (40) are respectively installed at the left end and the right end of the air conveying cavity (41) in a sliding mode, and one end of the first connecting cavity (39) and one end of the second connecting cavity (40) penetrate through the air conveying cavity (41);

the first connecting cavity (39) and the second connecting cavity (40) are fixedly arranged on the left outer wall and the right outer wall of a piston (42) respectively;

the piston (42) is connected to the inside of the air conveying cavity (41) in a sliding mode;

a first air spring (43) and a second air spring (44) are fixedly connected between the first connecting cavity (39) and the piston (42) and the second connecting cavity (40) respectively;

the first air spring (43) and the second air spring (44) are fixed on the outer part of a piston (42) at one end and are fixedly connected on the inner wall of the air conveying cavity (41) at the other end, and the first connecting cavity (39) and the second connecting cavity (40) respectively penetrate through the first air spring (43) and the second air spring (44);

the piston (42) is communicated with the air conveying cavity (41), and a fourth air conveying pipe (45) communicated with the piston (42) is fixedly connected to the center of the piston (42).

9. The heat dissipating device for a software development computer according to claim 1, wherein:

the box (1) comprises: the outer box body and the inner box body are arranged on the inner side of the outer box body, a cooling pipe is wound on the outer surface of the inner box body, and a water inlet of the cooling pipe is connected with a cooling water source through a micro water pump;

the server heat dissipation device for software development further comprises a first temperature sensor, a second temperature sensor, a flow velocity sensor, a controller and an alarm;

the first temperature sensor is used for detecting the surface temperature of the cooling pipe;

the second temperature sensor is used for detecting the surface temperature of the outer box body;

the flow velocity sensor is used for detecting the flow velocity of the liquid output by the micro water pump;

the controller stores theoretical unit length heat loss of the cooling pipe and heat exchange coefficient of the theoretical cooling pipe;

the controller is electrically connected with the first temperature sensor, the second temperature sensor, the flow rate sensor and the alarm;

the controller is based on first temperature sensor, second temperature sensor, flow rate sensor control alarm report to the police, includes:

calculating the heat loss of the cooling pipe per unit length through a formula (1) based on the surface temperature of the cooling pipe detected by the first temperature sensor, the surface temperature of the outer box detected by the second temperature sensor and the flow rate of the liquid output by the micro water pump detected by the flow rate sensor;

heat loss per unit length of the cooling tube;

in formula (1), s₁The heat transfer coefficient of the cooling pipe is shown, wherein pi is the circumference ratio and takes a value of 3.14, d is the inner diameter of the cooling pipe, and s₂Denotes the heat transfer coefficient of the case, b denotes the average distance between the outer case and the inner case, λ denotes the heat conductivity of the cooling pipe, T₂Represents an average value, T, of values detected by the second temperature sensor during a target time₁Represents an average value of values detected by the first temperature sensor over a target time,

the order of the bottom is 2,

the logarithm of (d); e is a constant, the value is 2.72, K is the average error coefficient of the first temperature sensor and the second temperature sensor, and eta is the surface cleaning coefficient of the cooling pipe;

calculating the actual heat exchange coefficient of the cooling pipe based on the flow speed of the liquid output by the micro water pump detected by the flow speed sensor and a formula (2);

the actual heat exchange coefficient r of the cooling pipe;

in the formula (2), q is the theoretical unit length heat loss of the cooling pipe, v is the average value of the detection values of the flow velocity sensor in the target time, and n is the kinematic viscosity of the liquid output by the micro water pump (10);

and when the calculated actual heat exchange coefficient of the cooling pipe is smaller than the heat exchange coefficient of the theoretical cooling pipe stored in the controller, the controller triggers an alarm device to give an alarm.

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