CN112543588B

CN112543588B - Method and system for improving performance of ultrathin heat dissipation film

Info

Publication number: CN112543588B
Application number: CN202011490241.0A
Authority: CN
Inventors: 刘勇; 李永刚
Original assignee: Nanjing Beidi New Material Technology Co ltd
Current assignee: Nanjing Beidi New Material Technology Co ltd
Priority date: 2020-12-15
Filing date: 2020-12-15
Publication date: 2021-08-17
Anticipated expiration: 2040-12-15
Also published as: CN112543588A

Abstract

The invention discloses a method and a system for improving the performance of an ultrathin heat dissipation film, wherein the method comprises the following steps: obtaining first target device information; obtaining first outdoor temperature information of a first season; obtaining a first preset time period; acquiring first real-time temperature information of target use equipment under first outdoor temperature information; obtaining a first degree of influence of the first real-time temperature information on the performance of the first target device; judging whether the first influence degree exceeds a preset influence degree threshold value or not; if the first outdoor temperature information exceeds the first outdoor temperature information, obtaining a first real-time heating rate of the first target equipment under the first outdoor temperature information; obtaining first preparation scheme information and first heat dissipation coefficient information of the ultrathin heat dissipation film; judging whether the first heat dissipation coefficient information of the ultrathin heat dissipation film meets the heat dissipation requirement information of the first real-time heating rate; if not, a first adjustment instruction is obtained. The technical problem that the existing heat dissipation technology cannot meet the heat dissipation requirement of the next generation of mobile equipment is solved.

Description

Method and system for improving performance of ultrathin heat dissipation film

Technical Field

The invention relates to the technical field of heat dissipation of mobile equipment, in particular to a method and a system for improving the performance of an ultrathin heat dissipation film.

Background

Mobile devices have been increasingly data processing speed due to their multiple capabilities, including high quality cameras and video games. However, mobile devices are becoming thinner and thinner. The increased functionality and reduced thickness of these devices results in extremely dense packs with a significant increase in the amount of heat generated in each square cell. Thus, overheating of local components in these devices has become a significant challenge.

However, in the process of implementing the technical solution of the invention in the embodiments of the present application, the inventors of the present application find that the above-mentioned technology has at least the following technical problems:

the existing heat dissipation technology is based on ultrathin graphite or graphene plates, and cannot meet the heat dissipation requirement of the next generation.

Disclosure of Invention

The embodiment of the application provides a method and a system for improving the performance of an ultrathin radiating film, solves the technical problem that the existing radiating technology cannot meet the radiating requirement of the next generation of mobile equipment, and achieves the technical effect that the advanced heat pipe inner wick structure is developed by utilizing a micro/nano manufacturing technology to improve the performance of the ultrathin radiating film so as to fully radiate the local parts in the equipment due to overheating.

The embodiment of the application provides a method for improving the performance of an ultrathin heat dissipation film, wherein the method comprises the following steps: obtaining first target device information, wherein the first target device is a target use device of the ultrathin heat dissipation film; obtaining first outdoor temperature information for a first season, wherein the first season is summer; obtaining a first preset time period; according to the first preset time period, first real-time temperature information of the target use equipment under the first outdoor temperature information is obtained; obtaining a first degree of influence of the first real-time temperature information on the performance of the first target device; judging whether the first influence degree exceeds a preset influence degree threshold value or not; if yes, obtaining a first real-time heat generation rate of the first target device under the first outdoor temperature information; obtaining first preparation scheme information and first heat dissipation coefficient information of the ultrathin heat dissipation film; judging whether the first heat dissipation coefficient information of the ultrathin heat dissipation film meets the heat dissipation requirement information of the first real-time heating rate or not according to the first preparation scheme information; and if not, obtaining a first adjusting instruction, wherein the first adjusting instruction is used for adjusting the first preparation scheme.

In another aspect, the present application further provides a system for improving the performance of an ultra-thin heat dissipation film, wherein the system comprises: a first obtaining unit: the first obtaining unit is used for obtaining first target device information, wherein the first target device is a target using device of the ultrathin heat dissipation film; a second obtaining unit: the second obtaining unit is used for obtaining first outdoor temperature information of a first season, wherein the first season is summer; a third obtaining unit: the third obtaining unit is used for obtaining a first preset time period; a fourth obtaining unit: the fourth obtaining unit is configured to obtain first real-time temperature information of the target user equipment under the first outdoor temperature information according to the first preset time period; a fifth obtaining unit: the fifth obtaining unit is configured to obtain a first degree of influence of the first real-time temperature information on the performance of the first target device; a first judgment unit: the first judging unit is used for judging whether the first influence degree exceeds a preset influence degree threshold value; a sixth obtaining unit: the sixth obtaining unit is used for obtaining a first real-time heat generation rate of the first target device under the first outdoor temperature information if the first real-time heat generation rate exceeds the first outdoor temperature information; a seventh obtaining unit: the seventh obtaining unit is used for obtaining first preparation scheme information and first heat dissipation coefficient information of the ultrathin heat dissipation film; a second judgment unit: the second judging unit is used for judging whether the first heat dissipation coefficient information of the ultrathin heat dissipation film meets the heat dissipation requirement information of the first real-time heating rate or not according to the first preparation scheme information; an eighth obtaining unit: the eighth obtaining unit is configured to, if the first adjustment instruction is not satisfied, obtain a first adjustment instruction, where the first adjustment instruction is used to adjust the first preparation scheme.

One or more technical solutions provided in the embodiments of the present application have at least the following technical effects or advantages:

through with ultra-thin radiating film is applied to the target equipment who contains smart mobile phone, panel computer and notebook computer etc. through the contrast installation the temperature information of cell-phone around the ultra-thin radiating film is judged whether first coefficient of heat dissipation information of ultra-thin radiating film satisfies the heat dissipation demand information of first real-time rate of heat generation has reached accurate obtaining judgement result, and then has improved the technological effect of ultra-thin radiating film performance.

The foregoing description is only an overview of the technical solutions of the present application, and the present application can be implemented according to the content of the description in order to make the technical means of the present application more clearly understood, and the following detailed description of the present application is given in order to make the above and other objects, features, and advantages of the present application more clearly understandable.

Drawings

FIG. 1 is a schematic flow chart illustrating a method for improving the performance of an ultra-thin heat dissipation film according to an embodiment of the present disclosure;

FIG. 2 is a schematic structural diagram of a system for improving the performance of an ultra-thin heat-dissipating film according to an embodiment of the present disclosure;

fig. 3 is a schematic structural diagram of an exemplary electronic device according to an embodiment of the present application.

Description of reference numerals: a first obtaining unit 11, a second obtaining unit 12, a third obtaining unit 13, a fourth obtaining unit 14, a fifth obtaining unit 15, a first judging unit 16, a sixth obtaining unit 17, a seventh obtaining unit 18, a second judging unit 19, an eighth obtaining unit 20, a bus 300, a receiver 301, a processor 302, a transmitter 303, a memory 304, and a bus interface 305.

Detailed Description

Hereinafter, example embodiments according to the present application will be described in detail with reference to the accompanying drawings. It should be apparent that the described embodiments are merely some embodiments of the present application and not all embodiments of the present application, and it should be understood that the present application is not limited to the example embodiments described herein.

Summary of the application

Mobile devices have been increasingly data processing speed due to their multiple capabilities, including high quality cameras and video games. However, mobile devices are becoming thinner and thinner. The increased functionality and reduced thickness of these devices results in extremely dense packs with a significant increase in the amount of heat generated in each square cell. Thus, overheating of local components in these devices has become a significant challenge. The existing heat dissipation technology is based on ultrathin graphite or graphene plates, and cannot meet the heat dissipation requirement of the next generation.

In view of the above technical problems, the technical solution provided by the present application has the following general idea:

For better understanding of the above technical solutions, the following detailed descriptions will be provided in conjunction with the drawings and the detailed description of the embodiments.

Example one

As shown in fig. 1, an embodiment of the present application provides a method for improving performance of an ultra-thin heat dissipation film, where the method further includes:

step S100: obtaining first target device information, wherein the first target device is a target use device of the ultrathin heat dissipation film;

specifically, it is required to improve the performance of the ultra-thin heat dissipation film, and first target device information, which is a target use device of the ultra-thin heat dissipation film and is applicable to smart terminals such as a tablet computer, a notebook computer, and a mobile phone, may be obtained first. The heat dissipation film is a layer of heat-conducting and heat-dissipating film used on a mobile phone, a tablet computer, and the like, and is roughly divided into four types: natural graphite, artificial graphite, graphene and carbon nanotube heat dissipation films.

Step S200: obtaining first outdoor temperature information for a first season, wherein the first season is summer;

particularly, still can obtain the first outdoor temperature information in first season, because of there is the difference in outdoor temperature information, lead to the heat dispersion of target user equipment has the difference, first season is summer, when being in summer, because of outdoor temperature is higher, leads to the cell-phone can not in time dispel the heat etc..

Step S300: obtaining a first preset time period;

step S400: according to the first preset time period, first real-time temperature information of the target use equipment under the first outdoor temperature information is obtained;

specifically, a first preset time period may also be obtained, where the first preset time period is a time period to be waited outdoors, and may be a time period of half an hour or an hour, and no specific setting is made here, and further according to the first preset time period, first real-time temperature information of the target user equipment under the first outdoor temperature information is obtained, which may be further understood as real-time heating information of a mobile phone when a user uses the mobile phone outdoors in summer.

Step S500: obtaining a first degree of influence of the first real-time temperature information on the performance of the first target device;

specifically, the first real-time temperature information is known, and then the first influence degree of the first real-time temperature information on the performance of the first target device is obtained, so that the mobile phone is difficult to radiate when a user uses the mobile phone outdoors in summer due to overhigh outdoor temperature, and the mobile phone is easy to radiate when the user uses the mobile phone outdoors in winter due to overlow outdoor temperature, so that the influence of summer on the heat radiation performance of the mobile phone is large, and the influence of summer on the heat radiation performance of the mobile phone is small in winter.

Step S600: judging whether the first influence degree exceeds a preset influence degree threshold value or not;

step S700: if yes, obtaining a first real-time heat generation rate of the first target device under the first outdoor temperature information;

specifically, knowing the first influence degree, it may be determined whether the first influence degree exceeds a preset influence degree threshold, where the preset influence degree threshold is a preset influence degree that the first target device can bear, and when the first influence degree exceeds the preset influence degree threshold, that is, the heat dissipation rate of the mobile phone exceeds the bearable influence degree, a first real-time heat generation rate of the first target device under the first outdoor temperature information is obtained, where the first real-time heat generation rate is a heat generation rate of the first target device per unit time within a first preset time period.

Step S800: obtaining first preparation scheme information and first heat dissipation coefficient information of the ultrathin heat dissipation film;

specifically, first preparation scheme information and first heat dissipation coefficient information of the ultrathin heat dissipation film can be obtained, the first preparation scheme information is information of a preparation scheme, a preparation process and the like of the ultrathin heat dissipation film, and the first heat dissipation coefficient information is heat dissipation capacity information of the ultrathin heat dissipation film.

Step S900: judging whether the first heat dissipation coefficient information of the ultrathin heat dissipation film meets the heat dissipation requirement information of the first real-time heating rate or not according to the first preparation scheme information;

step S1000: and if not, obtaining a first adjusting instruction, wherein the first adjusting instruction is used for adjusting the first preparation scheme.

Specifically, it is known that the first preparation scheme information and the first heat dissipation coefficient information can also be determined according to the first preparation scheme information, that is, whether the first heat dissipation coefficient information of the ultra-thin heat dissipation film meets the heat dissipation requirement information of the first real-time heat generation rate is determined by comparing the first real-time heat generation rate with the first heat dissipation coefficient information, that is, whether the ultra-thin heat dissipation film meets the heat dissipation requirement of the first target device is determined, and when the first real-time heat generation rate is not met, a first adjustment instruction is obtained, and the first adjustment instruction is to adjust the first preparation scheme, so that the prepared ultra-thin heat dissipation film meets the heat dissipation requirement of the first target device, and the technical effect of improving the performance of the ultra-thin heat dissipation film is achieved.

The step S900 of determining whether the first heat dissipation coefficient information of the ultra-thin heat dissipation film satisfies the heat dissipation requirement information of the first real-time heat generation rate according to the first preparation scheme information further includes:

step S910: obtaining first target temperature information according to the performance of the first target equipment;

step S920: obtaining a second preset time period;

step S930: after the ultrathin heat dissipation film is installed on the first target device, second real-time temperature information of the first target device is obtained after the second preset time period;

step S940: and comparing the second real-time temperature information with the first target temperature information, and judging whether the first heat dissipation coefficient information of the ultrathin heat dissipation film meets the heat dissipation requirement information of the first real-time heating rate.

Specifically, in order to further determine whether the first heat dissipation coefficient information of the ultra-thin heat dissipation film satisfies the heat dissipation requirement information of the first real-time heat dissipation rate, first target temperature information may be obtained according to the performance of the first target device, where the first target temperature information is temperature information of the first target device, when the performance of the first target device is better, the heat dissipation degree of the first target device is better, the first target temperature information is lower, and a second preset time period may also be obtained, where the second preset time period is a second preset time period in which a user uses a mobile phone after the first preset time period, and further, after the ultra-thin heat dissipation film is installed on the first target device, after the second preset time period, the second real-time temperature information of the first target device is obtained, and the second real-time temperature information is temperature information of the mobile phone after the ultra-thin heat dissipation film is installed on the mobile phone, through with second real-time temperature information with first target temperature information compares, judges whether first coefficient of heat dissipation information of ultra-thin radiating film satisfies the heat dissipation demand information of first real-time rate of heating, through the contrast installation promptly the temperature information of cell-phone around the ultra-thin radiating film is judged whether first coefficient of heat dissipation information of ultra-thin radiating film satisfies the heat dissipation demand information of first real-time rate of heating has reached the technological effect of accurate acquisition judged result.

Further, the embodiment of the application further comprises:

step S1110: obtaining first condenser information according to the first preparation scheme;

step S1120: obtaining trickle condensation information of the first condenser;

step S1130: obtaining first rate information of condensate removal of the first condenser according to the trickle condensation information;

step S1140: judging whether the first rate information meets a preset rate range or not;

step S1150: and if not, obtaining a second adjusting instruction, wherein the second adjusting instruction is used for adjusting the first condenser information.

In particular, in order to improve the performance of the ultra-thin heat dissipation film, first condenser information can be obtained according to the first preparation scheme, and it can be further understood that, when designing and manufacturing an ultra-thin and super-conductive copper heat pipe for thermal management of a mobile device (such as a smart phone), the condenser is a key component and consists of micro-pyramids coated with nano-wires, and the micro/nano-scale materials can enable the heat pipe to have high thermal conductivity and can convert gas or vapor into liquid to transfer heat in the pipe to air in the vicinity of the pipe in a quick manner. And then obtaining trickle condensation information of the first condenser, wherein the condenser converts gas or vapor into liquid, so the condensation mode is usually trickle condensation, and then according to the trickle condensation information, first speed information of the first condenser for removing condensate is obtained, for the condenser, the trickle condensation is mainly promoted, and the condensate is removed as fast as possible, so the first speed information is the speed of the condenser for removing condensate, whether the first speed information meets a preset speed range is further judged, the preset speed information is preset speed information of the condenser for removing condensate, when the first speed information does not meet the preset speed range, a second adjusting instruction is obtained, and the second adjusting instruction is used for adjusting the first condenser information, so that the technical effects of promoting the trickle condensation and removing the condensate as fast as possible are achieved.

If not, obtaining a second adjusting instruction, where the second adjusting instruction is used to adjust the first condenser information, and step S1150 further includes:

step S1151: obtaining a first weight ratio of the first rate information to the first heat dissipation coefficient information;

step S1152: obtaining first nanowire structure information according to the first condenser information, wherein the first nanowire structure information comprises micro pyramid structure information;

step S1153: obtaining a third adjustment instruction;

step S1154: and adjusting the micro pyramid structure information according to the third adjusting instruction and the first weight ratio.

Specifically, in order to further adjust the first condenser information, a first weight ratio of the first rate information to the first heat dissipation coefficient information may be obtained, namely the influence of the condensate removing speed of the condenser on the heat dissipation coefficient of the ultrathin heat dissipation film, and can obtain first nanowire structural information according to the first condenser information, the first nano-structure information comprises micro pyramid structure information, and micro/nano-scale materials can enable the heat pipe to have high thermal conductivity, so that the nano-structure information has great influence on the thermal conductivity of the heat pipe, further obtaining a third adjusting instruction, wherein the third adjusting instruction is to adjust the micro pyramid structure information according to the first weight to make the micro pyramid structure uniform, and then the temperature is uniformly distributed on the heat pipe, thereby achieving the technical effect of uniformly radiating the heat pipe.

Further, the embodiment of the application further comprises:

step 1210: obtaining first working fluid information according to the first preparation scheme;

step S1220: obtaining quality information of the first working fluid;

step S1230: judging whether the quality information of the first working solution meets a preset quality requirement or not;

step S1240: and if not, obtaining a fourth adjusting instruction, wherein the fourth adjusting instruction is used for adjusting the first working fluid.

Specifically, in order to improve the performance of the ultra-thin heat dissipation film, first working fluid information can be obtained according to the first preparation scheme, and further, the information can be understood that the information is filled with acetone as the working fluid and is more than 30 times higher than that of pure copper when the power is 91.3W, the effective thermal conductivity coefficient of the heat pipe can reach 12270W/(m.K), and the quality information of the first working solution can be obtained, wherein the quality information is the physical and chemical information of acetone and the like, further judging whether the quality information of the first working fluid meets a preset quality requirement, wherein the preset quality requirement is the quality required by a preset acetone filling fluid, if not, obtaining a fourth adjusting instruction, wherein the fourth adjusting instruction is to adjust the first working fluid, the quality of the first working solution meets the required quality standard, and the technical effect of improving the performance of the ultrathin heat dissipation film is achieved.

Further, the step S1220 of obtaining the quality information of the first working fluid further includes:

step S1221: inputting the first working fluid information into a first training model, wherein the first training model is obtained by training a plurality of groups of training data, and each group of the plurality of groups of training data comprises: the first working fluid information and identification information identifying a first result;

step S1222: obtaining first output information of the first training model, wherein the first output information comprises the first result, and the first result comprises quality information for identifying the first working fluid.

Specifically, in order to obtain the quality information of the first working fluid, the first working fluid information may be input into a first training model for continuous training, so that the output training result may be more accurate. The training model is a Neural network model, namely a Neural network model in machine learning, and a Neural Network (NN) is a complex Neural network system formed by widely interconnecting a large number of simple processing units (called neurons), reflects many basic characteristics of human brain functions, and is a highly complex nonlinear dynamical learning system. Neural network models are described based on mathematical models of neurons. Artificial Neural Networks (Artificial Neural Networks) are a description of the first-order properties of the human brain system. Briefly, it is a mathematical model. In the embodiment of the application, the first working fluid information is input into a first training model for continuous training, and the first result information of the identification is used for training the neural network model.

Further, the process of training the neural network model is substantially a process of supervised learning. The plurality of groups of training data are specifically: the first operating fluid information and identification information identifying the first result. The neural network model outputs a training result by inputting the first working fluid information, namely the first result comprises quality information for identifying the first working fluid, the output information is verified with the first result information for identifying, and if the output information is consistent with the first result information for identifying, the data supervised learning is finished, and then the next group of data supervised learning is carried out; and if the output information is not consistent with the first result information requirement for playing the identification role, the neural network learning model adjusts itself until the output result of the neural network learning model is consistent with the first result information requirement for playing the identification role, and then the supervised learning of the next group of data is carried out. The neural network learning model is continuously corrected and optimized through training data, the accuracy of the neural network learning model in processing the information is improved through the process of supervised learning, and the technical effect that the quality information of the first working solution is more accurate is achieved.

Further, the embodiment of the application further comprises:

step 1310: obtaining first evaporator information according to the first preparation scheme;

step S1320: obtaining second nanowire structure information according to the first evaporator information;

step S1330: when the first working fluid is evaporated through the first evaporator, obtaining first evaporation area information of the first evaporator;

step S1340: obtaining first heat dissipation area information of the first target device;

step S1350: judging whether the first evaporation area covers the first heat dissipation area or not;

step S1360: and if the first heat dissipation area cannot be covered, obtaining a fifth adjusting instruction, wherein the fifth adjusting instruction is used for adjusting the second nanowire structure information.

Specifically, in order to obtain the quality information of the first working fluid, first evaporator information can be obtained according to the first preparation scheme, further, the evaporator is a key component of the heat pipe and is controlled by a core-arranging structure, the evaporator is composed of layered micro-channels, nanowires are arranged on the top wall, the side wall and the bottom wall, and the evaporation of the film can be enhanced through the layered micro-channels, so that the liquid supply heating area is improved, and the drying is delayed. The second nano-structure information is critical to the thin film evaporation of the evaporator because the nano-structure forms a layered micro-channel of the evaporator, and meanwhile, when the first working solution is evaporated by the first evaporator, the first evaporation area information of the first evaporator is obtained, which can be further understood as that when the first evaporation area is larger, the working solution is evaporated faster, the first heat dissipation area information of the first target device can be obtained, which can be understood as the heat area of a local component when the mobile phone is used, such as a mobile phone battery, and the like, so as to judge whether the first evaporation area covers the first heat dissipation area, that is, whether the local heat generating component of the mobile phone can sufficiently dissipate heat, and if the first heat dissipation area cannot be covered, and obtaining a fifth adjusting instruction, wherein the fifth adjusting instruction is used for adjusting the second nanowire structure information, namely adjusting the distribution, arrangement and the like of the nanowires on the top, side and bottom walls, so that the first evaporation area covers the first heat dissipation area, and further the technical effect of fully dissipating heat of local heat generating components of the mobile phone is achieved.

To sum up, the method and the system for improving the performance of the ultrathin heat dissipation film provided by the embodiment of the application have the following technical effects:

1. through with ultra-thin radiating film is applied to the target equipment who contains smart mobile phone, panel computer and notebook computer etc. through the contrast installation the temperature information of cell-phone around the ultra-thin radiating film is judged whether first coefficient of heat dissipation information of ultra-thin radiating film satisfies the heat dissipation demand information of first real-time rate of heat generation has reached accurate obtaining judgement result, and then has improved the technological effect of ultra-thin radiating film performance.

2. Through adjusting the first preparation scheme information of the ultrathin heat dissipation film, the first condenser information, the micro pyramid structure information, the first working solution and the second nanowire structure information respectively, the technical effects of more precise and perfect preparation of the ultrathin heat dissipation film and further improvement of the performance of the ultrathin heat dissipation film are achieved.

Example two

Based on the same inventive concept as the method for improving the performance of the ultra-thin heat dissipation film in the foregoing embodiment, the present invention also provides a system for improving the performance of the ultra-thin heat dissipation film, as shown in fig. 2, the system comprising:

the first obtaining unit 11: the first obtaining unit 11 is configured to obtain first target device information, where the first target device is a target device of the ultra-thin heat dissipation film;

the second obtaining unit 12: the second obtaining unit 12 is configured to obtain first outdoor temperature information of a first season, where the first season is summer;

the third obtaining unit 13: the third obtaining unit 13 is configured to obtain a first preset time period;

the fourth obtaining unit 14: the fourth obtaining unit 14 is configured to obtain first real-time temperature information of the target user equipment under the first outdoor temperature information according to the first preset time period;

the fifth obtaining unit 15: the fifth obtaining unit 15 is configured to obtain a first degree of influence of the first real-time temperature information on the performance of the first target device;

the first judgment unit 16: the first judging unit 16 is configured to judge whether the first influence degree exceeds a preset influence degree threshold;

sixth obtaining unit 17: the sixth obtaining unit 17 is configured to, if the first real-time heat generation rate of the first target device under the first outdoor temperature information exceeds the first real-time heat generation rate, obtain a first real-time heat generation rate of the first target device under the first outdoor temperature information;

the seventh obtaining unit 18: the seventh obtaining unit 18 is configured to obtain first preparation scheme information and first heat dissipation coefficient information of the ultrathin heat dissipation film;

second determination unit 19: the second judging unit 19 is configured to judge whether the first heat dissipation coefficient information of the ultra-thin heat dissipation film meets the heat dissipation requirement information of the first real-time heat generation rate according to the first preparation scheme information;

the eighth obtaining unit 20: the eighth obtaining unit 20 is configured to, if not, obtain a first adjusting instruction, where the first adjusting instruction is used to adjust the first preparation scheme.

Further, the system further comprises:

a ninth obtaining unit: the ninth obtaining unit is configured to obtain first target temperature information according to the performance of the first target device;

a tenth obtaining unit: the tenth obtaining unit is used for obtaining a second preset time period;

an eleventh obtaining unit: the eleventh obtaining unit is configured to obtain second real-time temperature information of the first target device after the first target device is installed with the ultrathin heat dissipation film and after the second preset time period elapses;

a first comparison unit: the first comparison unit is used for comparing the second real-time temperature information with the first target temperature information and judging whether the first heat dissipation coefficient information of the ultrathin heat dissipation film meets the heat dissipation requirement information of the first real-time heating rate.

Further, the system further comprises:

a twelfth obtaining unit: the twelfth obtaining unit is used for obtaining first condenser information according to the first preparation scheme;

a thirteenth obtaining unit: the thirteenth obtaining unit is used for obtaining trickle condensation information of the first condenser;

a fourteenth obtaining unit: the fourteenth obtaining unit is used for obtaining first rate information of condensate removal of the first condenser according to the trickle condensation information;

a third judging unit: the third judging unit is used for judging whether the first speed information meets a preset speed range or not;

a fifteenth obtaining unit: the fifteenth obtaining unit is configured to obtain a second adjustment instruction if the first adjustment instruction is not satisfied, where the second adjustment instruction is used to adjust the first condenser information.

Further, the system further comprises:

a sixteenth obtaining unit: the sixteenth obtaining unit is configured to obtain a first weight ratio of the first rate information to the first thermal coefficient information;

a seventeenth obtaining unit: the seventeenth obtaining unit is configured to obtain first nanowire structure information according to the first condenser information, where the first nanowire structure information includes micro-pyramid structure information;

an eighteenth obtaining unit: the eighteenth obtaining unit is configured to obtain a third adjustment instruction;

a first adjusting unit: the first adjusting unit is used for adjusting the micro pyramid structure information according to the third adjusting instruction and the first weight ratio.

Further, the system further comprises:

a nineteenth obtaining unit: the nineteenth obtaining unit is used for obtaining first working solution information according to the first preparation scheme;

a twentieth obtaining unit: the twentieth obtaining unit is used for obtaining quality information of the first working fluid;

a fourth judging unit: the fourth judging unit is used for judging whether the quality information of the first working solution meets a preset quality requirement;

a twenty-first obtaining unit: the twenty-first obtaining unit is configured to obtain a fourth adjustment instruction if the first adjustment instruction is not satisfied, where the fourth adjustment instruction is used to adjust the first working fluid.

Further, the system further comprises:

a first input unit: the first input unit is used for inputting the first working fluid information into a first training model, the first training model is obtained through training of multiple groups of training data, and each group of the multiple groups of training data comprises: the first working fluid information and identification information identifying a first result;

a twenty-second obtaining unit: the twenty-second obtaining unit is configured to obtain first output information of the first training model, where the first output information includes the first result, and the first result includes quality information identifying the first working fluid.

Further, the system further comprises:

a twenty-third obtaining unit: the twenty-third obtaining unit is used for obtaining first evaporator information according to the first preparation scheme;

a twenty-fourth obtaining unit: the twenty-fourth obtaining unit is configured to obtain second nanowire structure information according to the first evaporator information;

a twenty-fifth obtaining unit: the twenty-fifth obtaining unit is configured to obtain first evaporation area information of the first evaporator when the first working fluid is evaporated by the first evaporator;

a twenty-sixth obtaining unit: the twenty-sixth obtaining unit is configured to obtain first heat dissipation area information of the first target device;

a fifth judging unit: the fifth judging unit is used for judging whether the first evaporation area covers the first heat dissipation area;

a twenty-seventh obtaining unit: the twenty-seventh obtaining unit is configured to obtain a fifth adjusting instruction if the first heat dissipation area cannot be covered, where the fifth adjusting instruction is used to adjust the second nanowire structure information.

Various modifications and embodiments of the method for improving the performance of the ultra-thin heat dissipation film in the first embodiment of fig. 1 are also applicable to the system for improving the performance of the ultra-thin heat dissipation film in the present embodiment, and through the foregoing detailed description of the method for improving the performance of the ultra-thin heat dissipation film, a person skilled in the art can clearly know an implementation method of the system for improving the performance of the ultra-thin heat dissipation film in the present embodiment, so for the brevity of the description, detailed description is omitted again.

EXAMPLE III

The electronic device of the embodiment of the present application is described below with reference to fig. 3.

Fig. 3 illustrates a schematic structural diagram of an electronic device according to an embodiment of the present application.

Based on the inventive concept of a method for improving the performance of an ultra-thin heat dissipation film as in the previous embodiment, the present invention further provides a system for improving the performance of an ultra-thin heat dissipation film, on which a computer program is stored, which when executed by a processor implements the steps of any one of the methods for improving the performance of an ultra-thin heat dissipation film as described above.

Where in fig. 3 a bus architecture (represented by bus 300), bus 300 may include any number of interconnected buses and bridges, bus 300 linking together various circuits including one or more processors, represented by processor 302, and memory, represented by memory 304. The bus 300 may also link together various other circuits such as peripherals, voltage regulators, power management circuits, and the like, which are well known in the art, and therefore, will not be described any further herein. A bus interface 305 provides an interface between the bus 300 and the receiver 301 and transmitter 303. The receiver 301 and the transmitter 303 may be the same element, i.e., a transceiver, providing a means for communicating with various other apparatus over a transmission medium. The processor 302 is responsible for managing the bus 300 and general processing, and the memory 304 may be used for storing data used by the processor 302 in performing operations.

As will be appreciated by one skilled in the art, embodiments of the present invention may be provided as a method, system, or computer program product. Accordingly, the present invention may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. Furthermore, the present invention may take the form of a computer program product embodied on one or more computer-usable storage media (including, but not limited to, disk storage, CD-ROM, optical storage, and the like) having computer-usable program code embodied therein.

The present invention is described with reference to flowchart illustrations and/or block diagrams of methods, apparatus (systems), and computer program products according to embodiments of the invention. It will be understood that each flow and/or block of the flow diagrams and/or block diagrams, and combinations of flows and/or blocks in the flow diagrams and/or block diagrams, can be implemented by computer program instructions. These computer program instructions may be provided to a processor of a general purpose computer, special purpose computer, embedded processor, or other programmable data processing apparatus to produce a machine, such that the instructions, which execute via the processor of the computer or other programmable data processing apparatus, create means for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be stored in a computer-readable memory that can direct a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including instruction means which implement the function specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be loaded onto a computer or other programmable data processing apparatus to cause a series of operational steps to be performed on the computer or other programmable apparatus to produce a computer implemented process such that the instructions which execute on the computer or other programmable apparatus provide steps for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

While preferred embodiments of the present invention have been described, additional variations and modifications in those embodiments may occur to those skilled in the art once they learn of the basic inventive concepts. Therefore, it is intended that the appended claims be interpreted as including preferred embodiments and all such alterations and modifications as fall within the scope of the invention.

It will be apparent to those skilled in the art that various changes and modifications may be made in the present invention without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.

Claims

1. A method of improving the performance of an ultra-thin heat spreading film, wherein the method comprises:

obtaining first target device information, wherein the first target device is a target use device of the ultrathin heat dissipation film;

obtaining first outdoor temperature information for a first season, wherein the first season is summer;

obtaining a first preset time period;

according to the first preset time period, first real-time temperature information of the target use equipment under the first outdoor temperature information is obtained;

obtaining a first degree of influence of the first real-time temperature information on the performance of the first target device;

judging whether the first influence degree exceeds a preset influence degree threshold value or not;

if yes, obtaining a first real-time heat generation rate of the first target device under the first outdoor temperature information;

obtaining first preparation scheme information and first heat dissipation coefficient information of the ultrathin heat dissipation film;

according to the first preparation scheme information, whether the first heat dissipation coefficient information of the ultrathin heat dissipation film meets the heat dissipation requirement information of the first real-time heating rate or not is judged, and the method comprises the following steps:

obtaining first target temperature information according to the performance of the first target equipment;

obtaining a second preset time period;

after the ultrathin heat dissipation film is installed on the first target device, second real-time temperature information of the first target device is obtained after the second preset time period;

comparing the second real-time temperature information with the first target temperature information, and judging whether the first heat dissipation coefficient information of the ultrathin heat dissipation film meets the heat dissipation requirement information of the first real-time heating rate;

and if not, obtaining a first adjusting instruction, wherein the first adjusting instruction is used for adjusting the first preparation scheme.

2. The method of claim 1, wherein the method further comprises:

obtaining first condenser information according to the first preparation scheme;

obtaining trickle condensation information of the first condenser;

obtaining first rate information of condensate removal of the first condenser according to the trickle condensation information;

judging whether the first rate information meets a preset rate range or not;

and if not, obtaining a second adjusting instruction, wherein the second adjusting instruction is used for adjusting the first condenser information.

3. The method of claim 2, wherein if not satisfied, obtaining a second adjustment instruction, wherein the second adjustment instruction is for adjusting the first condenser information, the method further comprising:

obtaining a first weight ratio of the first rate information to the first heat dissipation coefficient information;

obtaining first nanowire structure information according to the first condenser information, wherein the first nanowire structure information comprises micro pyramid structure information;

obtaining a third adjustment instruction;

and adjusting the micro pyramid structure information according to the third adjusting instruction and the first weight ratio.

4. The method of claim 1, wherein the method further comprises:

obtaining first working fluid information according to the first preparation scheme;

obtaining quality information of the first working fluid;

judging whether the quality information of the first working solution meets a preset quality requirement or not;

and if not, obtaining a fourth adjusting instruction, wherein the fourth adjusting instruction is used for adjusting the first working fluid.

5. The method of claim 4, wherein the obtaining quality information for the first working fluid further comprises:

inputting the first working fluid information into a first training model, wherein the first training model is obtained by training a plurality of groups of training data, and each group of the plurality of groups of training data comprises: the first working fluid information and identification information identifying a first result;

and obtaining first output information of the first training model, wherein the first output information comprises the first result, and the first result is quality information for identifying the first working fluid.

6. The method of claim 4, wherein the method further comprises:

obtaining first evaporator information according to the first preparation scheme;

obtaining second nanowire structure information according to the first evaporator information;

when the first working fluid is evaporated through the first evaporator, obtaining first evaporation area information of the first evaporator;

obtaining first heat dissipation area information of the first target device;

judging whether the first evaporation area covers the first heat dissipation area or not;

and if the first heat dissipation area cannot be covered, obtaining a fifth adjusting instruction, wherein the fifth adjusting instruction is used for adjusting the second nanowire structure information.

7. A system for improving the performance of an ultra-thin heat spreading film, wherein the system comprises:

a first obtaining unit: the first obtaining unit is used for obtaining first target device information, wherein the first target device is a target using device of the ultrathin heat dissipation film;

a second obtaining unit: the second obtaining unit is used for obtaining first outdoor temperature information of a first season, wherein the first season is summer;

a third obtaining unit: the third obtaining unit is used for obtaining a first preset time period;

a fourth obtaining unit: the fourth obtaining unit is configured to obtain first real-time temperature information of the target user equipment under the first outdoor temperature information according to the first preset time period;

a fifth obtaining unit: the fifth obtaining unit is configured to obtain a first degree of influence of the first real-time temperature information on the performance of the first target device;

a first judgment unit: the first judging unit is used for judging whether the first influence degree exceeds a preset influence degree threshold value;

a sixth obtaining unit: the sixth obtaining unit is used for obtaining a first real-time heat generation rate of the first target device under the first outdoor temperature information if the first real-time heat generation rate exceeds the first outdoor temperature information;

a seventh obtaining unit: the seventh obtaining unit is used for obtaining first preparation scheme information and first heat dissipation coefficient information of the ultrathin heat dissipation film;

a second judgment unit: the second judging unit is configured to judge whether the first heat dissipation coefficient information of the ultra-thin heat dissipation film satisfies the heat dissipation requirement information of the first real-time heat generation rate according to the first preparation scheme information, and includes:

obtaining a second preset time period;

an eighth obtaining unit: the eighth obtaining unit is configured to, if the first adjustment instruction is not satisfied, obtain a first adjustment instruction, where the first adjustment instruction is used to adjust the first preparation scheme.

8. A system for improving the performance of an ultra-thin heat spreading film, comprising a memory, a processor, and a computer program stored on the memory and executable on the processor, wherein the processor executes the program to perform the steps of the method of any one of claims 1-6.