阅读说明：本技术 一种强化滴状冷凝传热的微乳突-纳米线联合超疏水结构及其大面积制备工艺 (Micro-mastoid-nanowire combined super-hydrophobic structure for enhancing dropwise condensation heat transfer and large-area preparation process thereof ) 是由 杨晓龙 唐煜 朱荻 于 2021-09-02 设计创作，主要内容包括：本发明属于表面处理及特种加工领域,提供了一种强化滴状冷凝传热的微乳突-纳米线联合超疏水结构及其大面积制备工艺；该结构由微米乳突与纳米线联合组成,其中纳米线覆盖于微米乳突之上,微米乳突结构具有较高的曲率特征,能够提高液滴的运动性能；该工艺结合电化学技术、氧化刻蚀技术和表面能修饰技术在导电基底沉积并氧化刻蚀出微米级乳突与纳米线联合超疏水结构。本发明采用的微纳复合结构,对液滴的接触角迟滞较低,液滴的运动性能优异,其加工方法工艺简单、成本低廉、通用性强,可实现大面积跨尺度微乳突-纳米线联合超疏水结构的加工,在强化滴状冷凝传热、实现微尺度液滴操控、制造新型高性能热管和芯片实验室等方面具有重要应用价值。(The invention belongs to the field of surface treatment and special processing, and provides a micro-mastoid-nanowire combined super-hydrophobic structure for enhancing dropwise condensation heat transfer and a large-area preparation process thereof; the structure is formed by combining a micron mastoid and a nanowire, wherein the nanowire covers the micron mastoid, and the micron mastoid structure has a high curvature characteristic and can improve the motion performance of liquid drops; the process combines an electrochemical technology, an oxidation etching technology and a surface energy modification technology to deposit and oxidize and etch the micron-sized mastoid and nanowire combined super-hydrophobic structure on the conductive substrate. The micro-nano composite structure adopted by the invention has the advantages of lower contact angle hysteresis on liquid drops, excellent motion performance of the liquid drops, simple processing method, low cost and strong universality, can realize the processing of a large-area cross-scale micro mastoid-nanowire combined super-hydrophobic structure, and has important application value in the aspects of enhancing the drop-shaped condensation heat transfer, realizing the control of the micro-scale liquid drops, manufacturing novel high-performance heat pipes, chip laboratories and the like.)

1. A preparation method of a micro-mastoid-nanowire combined super-hydrophobic structure for enhancing dropwise condensation heat transfer is characterized by comprising the following steps:

(1) the structure is formed by combining a micron mastoid and a nanowire, wherein the nanowire covers the micron mastoid, the micron mastoid is in a shape of an inverted bowling pin, and the curvature radius of the top of the micron mastoid is 1-20 microns;

(2) depositing a microstructure layer on a conductive substrate by adopting an electrochemical deposition technology, and controlling the size of the surface microstructure of the electrodeposition layer by regulating and controlling the temperature, the proportion, the electrodeposition current density and the time of electrolyte to obtain the surface with a micron-sized mastoid structure, wherein the electrolyte is CuSO₄And H₂SO₄Mixing the solution;

(3) using KOH and K₂SO₄Carrying out oxidation etching on the micron-sized mastoid structure obtained in the step (2) by using the mixed solution, firstly cleaning the micron-sized mastoid structure by using deionized water after the etching is finished, then drying the micron-sized mastoid structure in a drying oven, and obtaining copper oxide nanowires on the surface of the micron-sized mastoid structure;

(4) and (4) soaking the micro-emulsion protrusion-nanowire combined structure manufactured in the step (3) in a fluorosilane-ethanol solution or performing chemical vapor deposition on a low-surface-energy molecular layer to obtain the super-hydrophobicity.

2. The micro-mastoid-nanowire combined super-hydrophobic structure for enhancing the dropwise condensation heat transfer and the large-area preparation process thereof as claimed in claim 1, wherein: in the step (1), the height of the micrometer mastoids is 5-50 μm, the gaps among the micrometer mastoids are 1-20 μm, and the diameter of the bottom of each micrometer mastoid is 1-20 μm.

3. The microemulsion for enhancing the dropwise condensation heat transfer according to claim 1-nanowire combined super-hydrophobic structure and large-area preparation process thereof, characterized in that: in step (2), CuSO₄And H₂SO₄In the mixed solution, CuSO₄The concentration is 0.5-3.0 mol/L, H₂SO₄The concentration is 0.5 to 5.0 mol/L.

4. The method for preparing the micro-papilla-nanowire combined super-hydrophobic structure for enhancing the dropwise condensation heat transfer as claimed in claim 1, wherein the method comprises the following steps: in the step (2), the temperature of the electrolyte is 10-70 ℃, and the current density is 1-100A/dm²The electrode gap is 0.2-20.0 mm, and the electrodeposition time is 3-9 min.

5. The method for preparing the micro-papilla-nanowire combined super-hydrophobic structure for enhancing the dropwise condensation heat transfer as claimed in claim 1, wherein the method comprises the following steps: in the step (3), the KOH concentration is 2.0-4.0 mol/L, K₂SO₄KOH and K at a concentration of 0.01 to 1.00mol/L₂SO₄The temperature of the mixed solution is 55-85 ℃.

6. The method for preparing the micro-papilla-nanowire combined super-hydrophobic structure for enhancing the dropwise condensation heat transfer as claimed in claim 1, wherein the method comprises the following steps: in the step (3), the etching time is 30-50 min; the drying condition is that the mixture is dried in an oven at 200 ℃ for 1 hour.

7. The micro-papilla-nanowire united superhydrophobic structure for enhancing the droplet-shaped condensation heat transfer prepared by the method of any one of claims 1-6.

8. The micro-papilla-nanowire associated superhydrophobic structure for enhancing droplet condensation heat transfer of claim 7, wherein: a large number of gaps exist among the micron-sized mastoid structures, so that the nano structures in the gaps can be effectively protected, and the nano structures are prevented from being abraded by external mechanical friction, and the mechanical robustness of the super-hydrophobic structure is enhanced.

9. The micro-papilla-nanowire associated superhydrophobic structure for enhancing droplet condensation heat transfer of claim 7, wherein: a large number of grooves exist among the micron-sized mastoid structures, the condensation liquid drops growing in the micro grooves can be extruded into the grooves in the condensation process, the condensation liquid drops are separated from the condensation surface through absorption, combination induction bounce and other forms, the timeliness of the drop-shaped condensation is enhanced, the duration time of the drop-shaped condensation can be as long as 10 hours or more, drying treatment is carried out on the drop-shaped condensation after 10 hours at 100-200 ℃, the drying time is 10-60 minutes, and the drop-shaped condensation characteristic can be recovered after drying.

10. The micro-papilla-nanowire associated superhydrophobic structure for enhancing droplet condensation heat transfer of claim 7, wherein: the micro-scale mastoid structure can enhance the droplet-shaped condensation heat transfer, and the condensation heat transfer coefficient can be increased by 500-600% compared with pure copper when the surface supercooling degree is 0.1-0.5 ℃.

Technical Field

The invention provides a micro-mastoid-nanowire combined super-hydrophobic structure for enhancing dropwise condensation heat transfer and a large-area preparation process thereof, belonging to the field of surface treatment and special processing.

Background

Condensation is a phase change phenomenon commonly existing in nature and is widely applied to the industrial fields of power generation, seawater desalination, heat transfer and the like. In all industrial applications, droplet condensation has a lower thermal resistance and a higher heat transfer coefficient than film condensation, since during droplet condensation steam condenses directly on the surface without passing through the liquid film. The micro-nano composite super-hydrophobic surface can effectively realize the drop condensation, and the surface has important application value in the aspects of enhancing the drop condensation and heat transfer. At present, the micro-nano composite super-hydrophobic surface is mainly manufactured by two or more combined processing methods, which mainly comprise etching, laser processing, photoetching and the like. For example, Xiao et al use laser to process micron-scale peak structures on the copper surface and obtain nanowires on the surface of the micron-scale structures by means of oxidation etching, which accelerates the growth rate of liquid drops in the process of drop-shaped condensation and enhances the heat transfer performance, the method can generate dust pollution in the laser processing process, and the mechanical properties of the base material can be reduced by the laser-ablated grooves [ ACS Nano,2019,13:8169 + 8184 ]; chander et al etch a micron-scale step-like structure on the surface of aluminum, and obtain a Nano-scale boehmite structure on the surface of the micron-scale structure by a hydrothermal method, thereby obtaining a micro-Nano composite superhydrophobic surface, which enhances spontaneous migration and bounce of droplets in the process of droplet condensation, the method has simple process, but the micron-scale pits generated in the etching process can destroy the mechanical properties of the substrate [ ACS Nano,2017,11: 1673-; chen et al process a micron-scale pyramid structure by photolithography, and then fabricate a nanowire on the surface of the micron structure by ion etching, which increases the number of droplets in the droplet-like condensation process and the size of the detached droplets, but the method has high processing accuracy, but the cost of large-area processing is high [ advanced Function Materials,2011,21: 4617-.

In summary, although the existing micro-nano composite super-hydrophobic surface is formed by combining an angular microstructure and a nanostructure, the curvature characteristic of the microstructure is not fully utilized to improve the motion performance of liquid drops; meanwhile, although the processing method can meet various processing requirements, the defects of air pollution in the processing process, high large-area processing cost, damage to the mechanical property of the base material and the like still exist, so that the micro-nano composite surface with high curvature characteristic is adopted, and a new technology of the large-area micro-nano composite super-hydrophobic surface, which is simple in process and strong in universality, is developed, so that the method has important application value in the aspects of enhancing dropwise condensation, realizing micro-scale liquid drop control, manufacturing novel high-performance heat pipes, chip laboratories and the like.

Disclosure of Invention

The invention provides a micro-mastoid-nanowire combined super-hydrophobic structure for enhancing the dropwise condensation heat transfer, and provides an electrochemical processing method which is environment-friendly, simple to operate, low in cost and suitable for large-area production for processing the structure.

In order to achieve the purpose, the technical scheme provided by the invention is as follows:

a preparation method of a micro-mastoid-nanowire combined super-hydrophobic structure for enhancing drop-shaped condensation heat transfer comprises the following steps:

(1) the structure is formed by combining a micron mastoid and a nanowire, wherein the nanowire covers the micron mastoid, the micron mastoid is in a shape of an inverted bowling pin, and the curvature radius of the top of the micron mastoid is 1-20 mu m;

(2) depositing a micron-sized structure layer on a conductive substrate by adopting an electrochemical deposition technology, and controlling the size of the micron-sized structure on the surface of an electrodeposition layer by regulating and controlling the temperature, the proportion, the electrodeposition current density and the time of an electrolyte to obtain the surface with a micron-sized mastoid structure, wherein the electrolyte is CuSO₄And H₂SO₄Mixing the solution;

(3) using KOH and K₂SO₄Carrying out oxidation etching on the micron-sized mastoid structure obtained in the step (2) by using the mixed solution, firstly cleaning the micron-sized mastoid structure by using deionized water after the etching is finished, then drying the micron-sized mastoid structure in a drying oven, and obtaining copper oxide nanowires on the surface of the micron-sized mastoid structure;

(4) and (4) soaking the micro-emulsion protrusion-nanowire combined structure manufactured in the step (3) in a fluorosilane-ethanol solution or performing chemical vapor deposition on a low-surface-energy molecular layer to obtain the super-hydrophobicity.

In the step (1), the height of the micron-sized mastoid is 5-50 μm, the gap between the micron-sized mastoids is 1-20 μm, and the diameter of the bottom of each micron-sized mastoid is 1-20 μm.

In step (2), CuSO₄And H₂SO₄In the mixed solution, CuSO₄The concentration is 0.5-3.0 mol/L, H₂SO₄The concentration is 0.5 to 5.0 mol/L.

In the step (2), the temperature of the electrolyte is 10-70 ℃, and the current density is 1-100A/dm²The electrode gap is 0.2-20.0 mm, and the electrodeposition time is 3-9 min.

In the step (3), the KOH concentration is 2.0-4.0 mol/L, K₂SO₄KOH and K at a concentration of 0.01 to 1.00mol/L₂SO₄The temperature of the mixed solution is 55-85 ℃.

In the step (3), the etching time is 30-50 min; the drying condition is that the mixture is dried in an oven at 200 ℃ for 1 hour.

The invention also protects the micro-mastoid-nanowire combined super-hydrophobic structure for enhancing the dropwise condensation heat transfer prepared by the method, and a large number of gaps exist among the micron-sized mastoid structures, so that the nano structures in the gaps can be effectively protected, and the nano structures are prevented from being abraded by external mechanical friction, and the mechanical robustness of the super-hydrophobic structure is enhanced.

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

1. the invention provides a micro-mastoid-nanowire combined super-hydrophobic structure for enhancing drop-shaped condensation heat transfer, wherein the nanowire structure covers the surface of a high-curvature micrometer structure, so that the contact angle delay of liquid drops on the surface is reduced, the driving force required by the movement of the liquid drops on the surface is reduced, and the movement performance of the liquid drops is improved.

2. In the droplet-shaped condensation-enhanced micro-emulsion bulge-nanowire combined super-hydrophobic structure, the surface of the microstructure is covered with the nanowire, so that the Laplace pressure gradient in gaps among the microstructures is enhanced, the hydrophobicity is improved, and power is provided for discharging condensate in the gaps.

3. The method for preparing the micro-nano composite structure on the copper surface by combining electrochemical deposition and oxidation etching is environment-friendly, simple to operate, low in cost and suitable for large-area production.

4. The micron-sized mastoid structure manufactured by the invention is deposited on the surface of the base material in an electrochemical deposition mode, and the mechanical property of the base material cannot be damaged.

5. A large number of gaps exist among the micron-sized mastoid-shaped structures manufactured by the method, the gaps can effectively protect the nano structures in the gaps and prevent the nano structures from being abraded by external mechanical friction, so that the mechanical robustness of the super-hydrophobic structure is enhanced, and experimental results show that the structure can bear the impact and friction of silicon dioxide particles with the mass of more than 100g falling freely from the height of 400mm, wherein the diameter range of the silicon dioxide particles is 140-400 mu m.

6. The micro-emulsion projection-nanowire combined super-hydrophobic structure can extrude condensation liquid drops growing in micro-grooves into the grooves in the condensation process, and the condensation liquid drops are separated from the condensation surface through absorption, combination induced bounce and other modes, so that the timeliness of drop condensation is enhanced, the heat transfer performance is improved, experimental results show that the surface can maintain the drop condensation for 10 hours, the drop condensation characteristic can be recovered after the surface is placed into a 100-DEG C drying oven for drying for 20 minutes after 10 hours, and the condensation heat transfer coefficient can be improved by 500-600% relative to pure copper when the supercooling degree is 0.5 ℃.

7. The microemulsion protrusion-nanowire combined super-hydrophobic structure manufactured by the invention can effectively block the penetration of condensate, thereby enhancing the corrosion resistance in the condensation process.

Drawings

FIG. 1 is a schematic diagram of the processing method of the present invention.

Fig. 2 is the intention of enhancing droplet squeezing, droplet merging and droplet merging bouncing in the droplet-shaped condensation process of the invention.

Fig. 3 is a schematic diagram of the microemulsion process-nanowire combined superhydrophobic structure of the present invention hindering condensate penetration.

FIG. 4 is a diagram of the effect of the processed micro-emulsion process-nano wire combined super-hydrophobic structure on enhancing condensation heat transfer.

FIG. 5 is a diagram showing the effect of the processed micro-emulsion process-nano wire combined super-hydrophobic structure to realize the dropwise condensation.

Number designation in the figures: 1. a tool anode; 2. an electrolyte; 3, a micro-emulsion structure; 4. a workpiece cathode; 5. an insulating clamp; 6. oxidizing the etching solution; 7. oxidizing and etching the obtained nano structure; 8. a fluorosilane ethanol solution or a low surface energy gas atmosphere of chemical vapor deposition; 9. condensed droplets of a superhydrophobic surface; a. droplets formed in the left gap by condensation; b. liquid drops formed by condensation on the tops of the micro-emulsion protrusions; c. droplets formed in the grooves on the right side by condensation; a + b and the 'a liquid drop' are extruded out of the left gap and then are combined with the 'b liquid drop' to form a liquid drop; the combination of a + b + c, a + b drop and c drop induces bouncing drops.

Detailed Description

The above-mentioned contents of the present invention are further described in detail by way of examples below, but it should not be understood that the scope of the above-mentioned subject matter of the present invention is limited to the following examples, and any technique realized based on the above-mentioned contents of the present invention falls within the scope of the present invention.

The experimental procedures used in the examples below are conventional procedures unless otherwise specified, and the reagents, methods and equipment used therein are conventional in the art unless otherwise specified.

The embodiment of the invention comprises the application of the method in the process of enhancing the dropwise condensation by adding a micro-emulsion protrusion-nanowire combined super-hydrophobic structure on a conductive substrate by utilizing an electrochemical processing technology and combining with the accompanying drawing.

Example 1

The method for processing the micro-mastoid-nanowire combined super-hydrophobic structure on the conductive substrate comprises the following steps:

(1) depositing a micron-sized mastoid-like structure on a conductive substrate by adopting an electrochemical deposition technology: with CuSO₄And H₂SO₄The mixed solution of (1) as an electrolyte, wherein CuSO₄Concentration of 0.5mol/L, H₂SO₄Is 1.0 mol/L; electrically insulating and protecting the non-processing surface of the workpiece cathode by using an insulating fixture, connecting the tool anode with the positive electrode of a power supply, connecting the workpiece cathode with the negative electrode of the power supply, injecting electrolyte to fill the gap between the tool anode and the workpiece cathode, controlling the temperature of the electrolyte to be 30 ℃ and the current density to be 5A/dm²The electrode gap is 5mm, electrodeposition is carried out for 3min, and a micron-sized mastoid structure is deposited on the surface of the cathode of the workpiece; the curvature radius of the top of the micron-sized mastoid-shaped structure is 3-20 microns, the height of the micron-sized mastoid is 5-20 microns, the gap between the micron-sized mastoids is 1-10 microns, and the diameter of the bottom of each micron-sized mastoid is 8-10 microns.

(2) On the basis of the obtained micron-sized papillary structure, the papillary structure is put into KOH and K₂SO₄Etching in the mixed solution (wherein the KOH concentration is 3.0mol/L, K)₂SO₄0.1mol/L, the temperature of the solution is 60 ℃), the substrate is taken out after etching for 40min and is washed by deionized water for 20min, and then the substrate is put into a 200 ℃ oven to be dried for 1 hour.

(3) On the basis of the micro-emulsion bump-nanowire combined structure manufactured in the last step, a low surface energy molecular layer is soaked in a fluorosilane-ethanol solution or deposited in a chemical vapor deposition manner to obtain super-hydrophobicity; in the droplet-shaped condensation process, the structure of the micro-emulsion protrusion-nanowire combination can extrude condensation droplets growing among the micro-emulsion protrusions out of the groove, and the condensation liquid is separated from the condensation surface through absorption, combination induced bounce and other forms, so that the timeliness of droplet-shaped condensation is enhanced, as shown in fig. 2.

Example 2

The method for processing the micro-mastoid-nanowire combined super-hydrophobic structure on the conductive substrate comprises the following steps:

(1) applying electrochemical deposition technique on conductive substrateDepositing a micron-sized mastoid structure: with CuSO₄And H₂SO₄The mixed solution of (1) as an electrolyte, wherein CuSO₄Concentration of 0.4mol/L, H₂SO₄Is 2.0 mol/L; electrically insulating and protecting the non-processing surface of the workpiece cathode by using an insulating fixture, connecting the tool anode with the positive electrode of a power supply, connecting the workpiece cathode with the negative electrode of the power supply, injecting electrolyte to fill the gap between the tool anode and the workpiece cathode, controlling the temperature of the electrolyte to be 40 ℃, and controlling the current density to be 15A/dm²Depositing a micron-sized mastoid structure on the surface of the cathode of the workpiece with an electrode gap of 2mm, and electrodepositing for 5min to deposit the micron-sized mastoid structure on the surface of the cathode of the workpiece; the curvature radius of the top of the micron-sized mastoid-shaped structure is 1-4 mu m, the height of the micron-sized mastoid is 5-30 mu m, the gap between the micron-sized mastoids is 1-15 mu m, and the diameter of the bottom of each micron-sized mastoid is 1-20 mu m.

(2) On the basis of the obtained micron-sized papillary structure, the papillary structure is put into KOH and K₂SO₄The mixed solution of (1) is etched, wherein the concentration of KOH is 2.0mol/L, K₂SO₄0.05mol/L and the temperature of the solution is 70 ℃; taking out after etching for 30min, cleaning with deionized water for 20min, and then drying in an oven at 200 ℃ for 1 h.

(3) On the basis of the micro-emulsion bump-nanowire combined structure manufactured in the last step, a low surface energy molecular layer is soaked in a fluorosilane-ethanol solution or deposited in a chemical vapor deposition manner to obtain super-hydrophobicity; in the droplet-shaped condensation process, the structure of the micro-emulsion protrusion-nanowire combination not only can extrude the grown condensate droplets among the micro-emulsion protrusions out of the groove, and make the condensate separate from the condensation surface through absorption, combination induced bounce and other forms, thereby enhancing the timeliness of droplet-shaped condensation, as shown in fig. 2, but also can prevent the condensate from permeating into the groove, thereby enhancing the corrosion resistance in the condensation process, as shown in fig. 3.

Example 3

The method for processing the micro-mastoid-nanowire combined super-hydrophobic structure on the conductive substrate comprises the following steps:

(1) depositing a micron-sized mastoid-like structure on a conductive substrate by adopting an electrochemical deposition technology:with CuSO₄And H₂SO₄The mixed solution of (1) as an electrolyte, wherein CuSO₄Concentration 1.5mol/L, H₂SO₄Is 2.5 mol/L; electrically insulating and protecting the non-processing surface of the workpiece cathode by using an insulating fixture, connecting the tool anode with the positive electrode of a power supply, connecting the workpiece cathode with the negative electrode of the power supply, injecting electrolyte to fill the gap between the tool anode and the workpiece cathode, controlling the temperature of the electrolyte to be 60 ℃ and the current density to be 8A/dm²The electrode gap is 4mm, the micron-sized mastoid structure is deposited on the surface of the cathode of the workpiece for electrodeposition for 9min, and the micron-sized mastoid structure is deposited on the surface of the cathode of the workpiece; the curvature radius of the top of the micron-sized mastoid-shaped structure is 2-30 mu m, the height of the micron-sized mastoid is 10-50 mu m, the gap between the micron-sized mastoids is 1-10 mu m, and the diameter of the bottom of each micron-sized mastoid is 10-100 mu m.

(2) On the basis of the obtained micron-sized papillary structure, the papillary structure is put into KOH and K₂SO₄The mixed solution of (1) is etched, wherein the concentration of KOH is 2.5mol/L, and K₂SO₄0.06mol/L, and the temperature of the solution is 60 ℃; taking out after etching for 45min, cleaning the substrate with deionized water for 20min, and then putting the substrate into an oven at 200 ℃ for drying for 1 hour.

(3) On the basis of the micro-emulsion process-nanowire combined structure manufactured in the last step, the low surface energy molecular layer is soaked in fluorosilane-ethanol solution or deposited in a chemical vapor deposition mode to obtain super-hydrophobicity. In the droplet-shaped condensation process, the structure of the micro-emulsion protrusion-nanowire combination not only can extrude the grown condensate droplets among the micro-emulsion protrusions out of the groove, and make the condensate separate from the condensation surface through absorption, combination induced bounce and other forms, so as to enhance the timeliness of droplet-shaped condensation, as shown in fig. 2, but also can prevent the condensate from permeating into the groove, so as to enhance the corrosion resistance in the condensation process, as shown in fig. 3, meanwhile, a large number of gaps exist among the micron-sized emulsion protrusion-shaped structures, and the gaps can effectively protect the nano structures in the gaps, prevent the nano structures from being worn by external mechanical friction, so as to enhance the mechanical robustness of the super-hydrophobic structure.

Example 4

The method for enhancing the dropwise condensation heat transfer by adopting the micro-mastoid-nanowire combined super-hydrophobic structure comprises the following steps:

the condensation experiment is carried out by adopting the surface of the micro-mastoid-nanowire combined super-hydrophobic structure, wherein the curvature radius of the top of the surface is 2-8 mu m, the height of the micro-mastoid is 5-20 mu m, the gap between the micro-mastoids is 2-10 mu m, and the diameter of the bottom of each micro-mastoid is 5-10 mu m. The environmental temperature is controlled to be 26 ℃, the relative humidity is 70%, the surface temperature of the micro-mastoid-nanowire combined super-hydrophobic structure is 5 ℃, the dropwise condensation time can last for more than 10 hours, and long-time dropwise condensation can be realized; after the condensation time exceeds 10 hours, the micro-emulsion protrusion-nano wire combined super-hydrophobic structure surface is dried, so that the hydrophobicity of the micro-emulsion protrusion-nano wire combined super-hydrophobic structure surface can be recovered to the hydrophobicity before 10 hours, the dropwise condensation performance of the micro-emulsion protrusion-nano wire combined super-hydrophobic structure surface can be recovered, and the condensation-drying-recovery process can be repeated for more than 5 times.

Example 5

The method adopts a micro-mastoid-nanowire combined super-hydrophobic structure to strengthen the dropwise condensation, and comprises the following specific steps:

carrying out condensation heat transfer experiments on the surface of the micro-mastoid-nanowire combined super-hydrophobic structure, wherein the curvature radius of the top of the micro-mastoid is 2-8 microns, the height of the micro-mastoid is 5-20 microns, the gaps among the micro-mastoid are 2-10 microns, and the diameter range of the bottom of each micro-mastoid is 5-10 microns; in a condensation cavity of pure water vapor without non-condensable gas, a contrast experiment of condensation effects of the surface of the micro-mastoid-nanowire combined super-hydrophobic structure and the surface of the pure copper is carried out, the temperature of the water vapor is 90 ℃, and when the supercooling degree is 0.5 ℃, the condensation heat transfer coefficient of the surface of the micro-mastoid-nanowire combined super-hydrophobic structure is improved by 500-600% relative to the surface of the pure copper, as shown in fig. 4.

The invention has simple process, low cost and strong universality, can realize the processing of large-area micro-mastoid-nano wire super-hydrophobicity on plane and curved substrates, and has important application value in the aspects of strengthening drop-shaped condensation, realizing micro-liter-scale liquid drop control, manufacturing novel high-performance heat pipes, chip laboratories and the like.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention in any way, and any person skilled in the art can make any simple modification, equivalent replacement, and improvement on the above embodiment without departing from the technical spirit of the present invention, and still fall within the protection scope of the technical solution of the present invention.