阅读说明：本技术 一种高效节能散热器的加工方法 (Processing method of high-efficiency energy-saving radiator ) 是由 王峰 于 2021-01-14 设计创作，主要内容包括：本发明提供了一种高效节能散热器的加工方法,加工方法步骤如下：铸模,根据实际使用时的情况,选择铸造规格形状适宜的散热器模具；熔炼,采取总含量百分之九十七的铝以及百分之三的铜为原料进行熔炼,熔炼为浇筑液以备使用；浇筑,将S2中熔炼完成的浇筑液,浇筑于S1中铸造完成的模具中,冷却脱模完成散热器的铸造；表面处理,将S3中铸造完成的散热器去油清洗后进行微弧氧化处理,微弧氧化中采用磷酸盐体系的碱性氧化电解液,散热器挂具采用铝合金材质,阴极采用不锈钢材质,微弧氧化时间为二十至三十分钟。本发明能够有效提升散热器散热效果,且微弧氧化处理后的散热器具有良好的耐磨、耐腐蚀、耐高温冲击和电绝缘性,能够提升热传导的散热性。(The invention provides a processing method of an efficient energy-saving radiator, which comprises the following steps: a casting mold, wherein a radiator mold with proper casting specification and shape is selected according to the actual use condition; smelting, namely smelting by taking aluminum with the total content of ninety-seven percent and copper with the total content of three percent as raw materials, and smelting into pouring liquid for later use; pouring, namely pouring the pouring liquid smelted in the step S2 into the die cast in the step S1, and cooling and demolding to finish casting of the radiator; and (3) surface treatment, namely performing micro-arc oxidation treatment after degreasing and cleaning the radiator cast in S3, wherein alkaline oxidation electrolyte of a phosphate system is adopted in the micro-arc oxidation, the radiator hanger is made of aluminum alloy, the cathode is made of stainless steel, and the micro-arc oxidation time is twenty to thirty minutes. The invention can effectively improve the heat dissipation effect of the radiator, and the radiator after micro-arc oxidation treatment has good wear resistance, corrosion resistance, high-temperature impact resistance and electrical insulation, and can improve the heat dissipation of heat conduction.)

1. A processing method of an efficient energy-saving radiator is characterized by comprising the following steps:

s1: a casting mold, wherein a radiator mold with proper casting specification and shape is selected according to the actual use condition;

s2: smelting, namely smelting by taking aluminum with the total content of ninety-seven percent and copper with the total content of three percent as raw materials, and smelting into pouring liquid for later use;

s3: pouring, namely pouring the pouring liquid smelted in the step S2 into the die cast in the step S1, and cooling and demolding to finish casting of the radiator;

s4: surface treatment, namely degreasing and cleaning the radiator cast in S3, then carrying out micro-arc oxidation treatment,

the micro-arc oxidation adopts alkaline oxidation electrolyte of a phosphate system, the radiator hanger is made of aluminum alloy, the cathode is made of stainless steel, and the micro-arc oxidation time is twenty to thirty minutes;

s5: cleaning, namely washing the radiator subjected to micro-arc oxidation treatment in S4 to remove impurities such as electrolyte and the like remained on the surface;

s6: and (5) polishing, namely roughly polishing and polishing the surface of the cleaned radiator to finish the machining and manufacturing of the heat dissipation.

2. The anti-aging flame-retardant cable insulation material as claimed in claim 1, wherein the aluminum raw material selected in the melting is an aluminum ingot with high purity, and the copper raw material selected in the melting is oxygen-free copper with high purity.

3. The anti-aging flame-retardant cable insulation material as claimed in claim 1, wherein the working voltage of the oxidation electrolyte in the micro-arc oxidation treatment is 500V-750V, and the pH value of the oxidation electrolyte in the micro-arc oxidation treatment is controlled between eight and thirteen.

4. The anti-aging flame-retardant cable insulation material according to claim 1, wherein the cleaning is carried out by washing with pure water.

5. The anti-aging flame-retardant cable insulation material as claimed in claim 1, wherein the polishing of the heat sink is performed by sequentially polishing the contact surface of the heat sink with five thousand to ten thousand meshes of abrasive paste.

Technical Field

The invention belongs to the technical field of radiator equipment, and particularly relates to a processing method of an efficient energy-saving radiator.

Background

The radiator is a mechanism which can be encountered in daily life and industrial production, and can play a role in radiating heat for working devices with higher temperature, most of the radiators are made of aluminum or aluminum alloy, and the aluminum alloy is an alloy which takes aluminum as a base and is added with a certain amount of other alloying elements and is one of light metal materials. In addition to the general characteristics of aluminum, aluminum alloys have certain alloy specific characteristics due to the variety and amount of alloying elements added.

However, when the existing radiator is used, the heat dissipation performance is poor, and the existing radiator is not corrosion-resistant and is easy to damage.

Disclosure of Invention

In view of this, the present invention is directed to a method for manufacturing an energy-efficient heat sink.

In order to achieve the purpose, the technical scheme of the invention is realized as follows:

a processing method of an efficient energy-saving radiator comprises the following steps:

s1: a casting mold, wherein a radiator mold with proper casting specification and shape is selected according to the actual use condition;

s2: smelting, namely smelting by taking aluminum with the total content of ninety-seven percent and copper with the total content of three percent as raw materials, and smelting into pouring liquid for later use;

s3: pouring, namely pouring the pouring liquid smelted in the step S2 into the die cast in the step S1, and cooling and demolding to finish casting of the radiator;

s4: performing surface treatment, namely performing micro-arc oxidation treatment after degreasing and cleaning the radiator cast in S3, wherein alkaline oxidation electrolyte of a phosphate system is adopted in the micro-arc oxidation, the radiator hanger is made of aluminum alloy, the cathode is made of stainless steel, and the micro-arc oxidation time is twenty to thirty minutes;

s5: cleaning, namely washing the radiator subjected to micro-arc oxidation treatment in S4 to remove impurities such as electrolyte and the like remained on the surface;

s6: and (5) polishing, namely roughly polishing and polishing the surface of the cleaned radiator to finish the machining and manufacturing of the heat dissipation.

Further, the aluminum raw material selected in the smelting is an aluminum ingot with high purity, and the copper raw material selected in the smelting is oxygen-free copper with high purity.

Furthermore, the working voltage of the oxidation electrolyte in the micro-arc oxidation treatment is 500V-750V, and the PH value of the oxidation electrolyte in the micro-arc oxidation treatment is controlled between eight and thirteen.

Further, pure water is adopted for washing during cleaning.

Furthermore, five thousand to ten thousand meshes of grinding paste is adopted for grinding the radiator, and the contact surface of the radiator is slightly ground in sequence.

Compared with the prior art, the repairing agent has the following advantages:

1. the radiator cast by adopting the aluminum with the total content of ninety-seven percent and the copper with three percent as the raw materials has the advantages of good heat dissipation performance, higher hardness, light weight, high room temperature and high temperature mechanical properties and simpler casting process; the cast radiator is subjected to micro-arc oxidation treatment after being degreased and cleaned, and the aluminum-copper alloy subjected to micro-arc oxidation treatment has good wear resistance, corrosion resistance, high-temperature impact resistance and electrical insulation, and can improve certain heat conduction heat dissipation performance;

2. according to the invention, the radiator is flushed by pure water, so that redundant impurities can be effectively cleaned, and the redundant impurities can be prevented from adhering to the surface of the radiator; the radiator is polished by adopting five-thousand to ten-thousand-mesh grinding paste to slightly polish and polish in sequence, so that the smoothness of the surface of the contact surface of the radiator can be improved, the fitting degree between the radiator and a device needing heat dissipation is improved, and the heat dissipation effect is improved.

Detailed Description

The present invention will be described in detail with reference to examples.

Example 1

A processing method of an efficient energy-saving radiator comprises the following steps:

s1: a casting mold, wherein a radiator mold with proper casting specification and shape is selected according to the actual use condition;

s2: smelting, namely smelting by taking aluminum with the total content of ninety-seven percent and copper with the total content of three percent as raw materials, and smelting into pouring liquid for later use;

s3: pouring, namely pouring the pouring liquid smelted in the step S2 into the die cast in the step S1, and cooling and demolding to finish casting of the radiator;

s4: performing surface treatment, namely performing micro-arc oxidation treatment after degreasing and cleaning the radiator cast in S3, wherein alkaline oxidation electrolyte of a phosphate system is adopted in the micro-arc oxidation, the radiator hanger is made of aluminum alloy, the cathode is made of stainless steel, and the micro-arc oxidation time is twenty to thirty minutes;

s5: cleaning, namely washing the radiator subjected to micro-arc oxidation treatment in S4 to remove impurities such as electrolyte and the like remained on the surface;

s6: and (5) polishing, namely roughly polishing and polishing the surface of the cleaned radiator to finish the machining and manufacturing of the heat dissipation.

Example 2

A processing method of an efficient energy-saving radiator comprises the following steps:

s1: a casting mold, wherein a radiator mold with proper casting specification and shape is selected according to the actual use condition;

s2: smelting, namely smelting by taking aluminum with the total content of ninety-seven percent and copper with the total content of three percent as raw materials, and smelting into pouring liquid for later use;

s3: pouring, namely pouring the pouring liquid smelted in the step S2 into the die cast in the step S1, and cooling and demolding to finish casting of the radiator;

s4: performing surface treatment, namely performing micro-arc oxidation treatment after degreasing and cleaning the radiator cast in S3, wherein alkaline oxidation electrolyte of a phosphate system is adopted in the micro-arc oxidation, the radiator hanger is made of aluminum alloy, the cathode is made of stainless steel, and the micro-arc oxidation time is twenty to thirty minutes;

s5: cleaning, namely washing the radiator subjected to micro-arc oxidation treatment in S4 to remove impurities such as electrolyte and the like remained on the surface;

s6: and (5) polishing, namely roughly polishing and polishing the surface of the cleaned radiator to finish the machining and manufacturing of the heat dissipation.

Example 3

The aluminum raw material selected in the smelting is an aluminum ingot with high purity, the copper raw material selected in the smelting is oxygen-free copper with high purity, and the aluminum with the total content of ninety-seven percent and the copper with the total content of three percent are used as raw materials for casting the radiator.

Example 4

The working voltage of the oxidation electrolyte in the micro-arc oxidation treatment is 500V-750V, the PH value of the oxidation electrolyte in the micro-arc oxidation treatment is controlled between eight and thirteen, and the aluminum-copper alloy subjected to the micro-arc oxidation treatment has good wear resistance, corrosion resistance, high-temperature impact resistance and electrical insulation, and can improve certain heat conduction heat dissipation.

Example 5

And pure water is adopted for washing during cleaning, so that redundant impurities are prevented from being remained on the surface of the radiator.

Example 6

The radiator is polished by adopting five-thousand to ten-thousand-mesh grinding paste to slightly polish the contact surface of the radiator in sequence, so that the smoothness of the surface of the contact surface of the radiator can be improved, the fitting degree between the radiator and a device needing heat dissipation is improved, and the heat dissipation effect is improved.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.