I. Nanophobic Hydrophilic Aluminum Foil Coating

1. Material Composition

Hydrophilic Polymer A: Primarily composed of polyether, providing basic hydrophilic properties.

Hydrophilic Nano-Polymer Particles B: Contains the following components:

Macromolecular surfactant (5–50% wt)

Acrylamide (20–90% wt)

Acrylic acid (10–80% wt)

Crosslinkable unsaturated monomer (1–30% wt)

Ratio: The mass ratio of Polymer A to B is 1:9 to 9:1.

2. Performance Characteristics

Excellent corrosion resistance

Superior self-lubricating ability

Long-lasting hydrophilic properties

3. Applications

Mainly used in aluminum heat exchange plates to enhance corrosion resistance and thermal efficiency.

II. Nano-Zirconia (CY-R200KR)

1. Basic Properties

Molecular Formula: ZrO₂

Molecular Weight: 123.22

Melting Point: 2397°C

Boiling Point: 4275°C

CAS No.: 1314-23-4

Characteristics: High hardness, insulating at room temperature, conductive at high temperatures

2. Product Features

Strong thermal shock resistance

High-temperature resistance

Excellent chemical stability

Outstanding composite material compatibility

3. Applications

Structural & Functional Ceramics: Improves fracture toughness and bending strength

Metal Material Modification: Enhances surface thermal conductivity and high-temperature oxidation resistance

Solid-State Batteries: Utilizes doped elements for improved conductivity

III. Nano-Alumina (VK-L05C)

1. Structural Ceramic Classification

Wear-resistant components

Structural parts

Refractory components

Carrier materials

Acid-resistant parts

Insulating components

2. Functions & Applications

IV. Anti-Friction Mechanism of Nano-Diamond

1. Ball Bearing Effect

Nano-diamond particles roll between friction surfaces, forming a "ball bearing" effect.

Sliding friction transforms into a mixed sliding-rolling friction, reducing wear.

2. Thin-Film Lubrication Effect

Carbon from nano-diamond penetrates the substrate under friction, forming a lubricating film.

Enhances surface hardness and minimizes direct contact, ideal for ultra-precision machining.

Nanomaterials (e.g., hydrophilic polymers, zirconia, alumina, diamond) have broad applications in corrosion resistance, lubrication, structural reinforcement, and functional ceramics. Their potential in advanced manufacturing, new energy, and biomedical fields is immense.