1、KH550, KH560, and KH570 modified SiO

In this study, the enhancement mechanism of SiO 2 modified by different silane coupling agents (SCA) on the moisture resistance, thermal properties and electrical insulation properties of epoxy resin (EP) composites is discussed.

2、Improving the Hydrophobicity and Insulation Properties of Epoxy Resins

Moreover, the electrical insulation performance of the modified epoxy resin was greatly improved when the surface resistivity and flashover voltage increased by 50.5 and 36.4%, respectively.

3、Evaluation of Insulation Performance and Life of Epoxy Resin Based on

In this paper, epoxy resin samples with different aging states are prepared, their FDS curves are tested, and a method for evaluating insulation aging of epoxy resin is proposed.

4、Preparation and Properties of Epoxy Modified Acrylic Polymer

The reaction mechanism of epoxy acrylate viscosity reducer was analyzed by Fourier transform infrared spectroscopy (FTIR). Additionally, the particle size and Zeta potential were used to analyze the stability of the polymer and the difference in the polymer after adding GMA monomer.

5、Improving the insulating performance of epoxy resin in humid

Thus, HTPDMS-modified epoxy resin insulation materials can maintain excellent insulation properties in humid environments, making them a promising application in the field of electronic packaging.

Optimizing dielectric, mechanical, and thermal properties of epoxy

This study introduces three molecular modifications to epoxy resin systems using facile synthesis procedures, including modifiers with bulky groups and crosslinking potential to reduce the dielectric constant while enhancing mechanical and thermal reliability, along with deep traps to increase breakdown strength.

Preparation and Properties of Epoxy Modified Acrylic Polymer

Thermogravimetric (TG) analysis indicated a significant improvement in the thermal stability of the resin due to GMA modification. The viscosity reduction test results demonstrated a substantial decrease in the viscosity of heavy oil, along with a notable increase in the viscosity reduction rate.

Improving thermal insulation properties of lightweight epoxy resin

In this study, a novel, lightweight, thermally insulated epoxy resin (EP) composite was designed and fabricated by arranging hollow glass microspheres/epoxy resin (HGMs/EP) hollow spheres and EP matrices using a combination of templates and a simple casting method.

Preparation and characteristics of silicone

In order to improve the aging resistance of epoxy resin insulation materials and the cost-effectiveness and reliability of power apparatuses, a novel silicone-modified aging-resistant epoxy resin insulation material was developed.

Study on the thermal properties and insulation resistance of epoxy

To study the effect of doping hexagonal boron nitride (h-BN) on the thermal properties and insulation resistance of epoxy resin (EP) and the mechanism of this effect, h-BN/epoxy composites with h-BN content of 0, 10, 20, 30, and 40 phr were prepared.

In modern architectural fields, the selection of materials directly impacts the insulation performance and energy efficiency of buildings. As a high-performance thermal insulation material, modified epoxy acrylic resin has become a top choice for numerous construction materials due to its excellent insulation properties, robust mechanical performance, and environmental friendliness. This article explores the insulation characteristics of modified epoxy acrylic resin and its significance in practical applications.

I. Basic Principles of Modified Epoxy Acrylic Resin

Modified epoxy acrylic resin is a thermosetting resin synthesized from an epoxy resin matrix, with specific functional fillers, plasticizers, curing agents, and other components added through a specialized process. This resin exhibits superior chemical stability, mechanical strength, and weather resistance. By incorporating functional groups such as fluorine or siloxane moieties into its molecular structure, it achieves exceptional insulation properties under normal temperatures.

II. Insulation Performance of Modified Epoxy Acrylic Resin

1. Low Thermal Conductivity: The thermal conductivity of modified epoxy acrylic resin is significantly lower than that of traditional insulation materials like polystyrene foam (EPS) and polyurethane (PU) foam. This means it can more effectively block heat transfer at the same thickness.

2. High-Temperature Resistance: The material maintains its insulation performance even under high-temperature conditions, thanks to the stability of its molecular structure, which prevents deformation and ensures long-term insulation effects.

3. Enhanced Anti-Aging Properties: It demonstrates excellent resistance to ultraviolet (UV) radiation and aging, preserving its insulation capabilities even after prolonged exposure to sunlight and temperature fluctuations.

4. Environmental Benefits: Free from harmful substances and recyclable, modified epoxy acrylic resin aligns with the development trends of green building materials.

III. Applications in Construction

1. Roof Insulation Layers: One of the most widespread applications is in roof insulation. Its superior performance reduces building energy consumption and improves energy utilization efficiency.

2. Wall Insulation: In exterior wall insulation systems, modified epoxy acrylic resin can be used as an inner lining material combined with outer layers to form a composite insulation system, enhancing wall thermal resistance.

3. Floor Insulation: For flooring engineering, the resin serves as an insulation layer to block upward heat conduction, thereby improving indoor comfort.

As global demands for energy conservation and emission reduction rise, modified epoxy acrylic resin has garnered significant attention due to its outstanding insulation properties. In the future, it will continue to play a critical role in building energy efficiency, contributing to the development of more eco-friendly and sustainable architectural environments.