글 찾기
폴리머 블렌드 수정 이론이란 무엇인가요?

Structure and morphology of polymer mixes

One of the most fundamental elements affecting the performance of polymer blends is their morphological structure. Polymer blends are heterogeneous, therefore various compositions have various morphological structures. Processing can cause even mixes of the same makeup to differ. Different environmental factors will also result in various morphological structures.

 

 

The characteristics of polymer blends are significantly altered by various morphological features. By examining the morphological structures of polymer alloys, we may determine the degree of compatibility between polymers and, in turn, determine the connection between the system’s composition, compatibility, microstructure, and mechanical properties.

 

Microstructure of a polymer alloy

(1) Amorphous polymer mix systems’ morphological properties

There are three main categories of morphological structure for amorphous polymer blend systems: interpenetrating two-phase continuous structure, two-phase interlocking (also known as staggered structure), and single-phase continuous structure.

(2) Crystalline polymer alloy morphological properties

Crystalline polymer alloys can be found in two different settings. In the blending system, one component is a crystalline polymer, while the other components are amorphous polymers. In the copolymer system, all of the polymers are crystalline polymers.

polymer spherulites

(3) Polymer blend alloy interface layer

The blended system of two polymers, which consists of the independent regions of the two polymers and the transition zone created between the two polymers, has three regional structures. The interface layer is the name of this transitional region. The blend’s performance is greatly influenced by the structure and properties of the interface layer, which express the degree of compatibility between the polymers in the blend and the strength of the bonds between the phases.
Creation of the interface layer: The polymer goes through two phases while being blended. The two polymers coming into contact with one another is the initial stage. The mutual diffusion of the two polymers’ macromolecular segments is the second stage. The creation of the two-phase interface layer is also a result of the mutual diffusion of macromolecular chains.

Polymer plus glass fiber microstructure

 

Polymer macromolecular segment mutual diffusion can occur in two different circumstances:

The two macromolecule segments will diffuse into one another at a similar rate if two polymer macromolecules have comparable mobilities;
The pace of diffusion between the two phases will be quite varied and may even be one-way if the mobility of the two macromolecules is significantly different. There is a clear concentration gradient in both phases as a result of the two polymers’ macromolecular segments diffusing among one another.

Thinness of the interface layer: The compatibility of the two polymers has a major impact on the interface’s thickness. An extremely clear and distinct phase contact between the two phases will be present when two polymers with poor compatibility are combined;

The degree of interdiffusion of the macromolecular segments of the two phases in the blend will be high if the two polymers are compatible, and the thickness of the interface layer between the two phases will be high. If the two polymers are completely miscible, the blend will have a sharp phase interface. When a homogeneous system is finally established, the phase interface vanishes entirely.
Interface adhesion: The chemical bonding between the two polymer macromolecules and the secondary valence force between the two phases are what determine how well two polymer surfaces adhere to one another. The interfacial tension is a major factor in determining the subvalent force’s size for the majority of polymer blends. The bonding strength increases as the interfacial tension between the two phases decreases. It is connected to the compatibility between polymers based on the extent of mutual diffusion of polymer segments. The stronger the interface’s adhesive strength and the better the blend’s mechanical qualities are, the better the compatibility.

최근 기사

나일론 인성 향상을 위해 적절한 POE 접목 무수 말레 산염을 선택하는 방법은 무엇입니까?

특히 보강 및 충진이 필요한 PA6, PA66 및 폴리아미드 시스템을 위한 충격 완화제로 설계된 Coace® W1A-F는 특별한 특성으로 인해 향상된 내충격성과 인성이 가장 중요한 용도에 완벽한 선택이 될 수 있습니다.

자세히 보기 →

PBT 개질의 새로운 돌파구: POE-g-GMA 강화제의 혁신적인 적용

PBT 개질에 POE-g-GMA 강화제를 사용하면 PBT 소재의 취성을 해결할 뿐만 아니라 새로운 플라스틱 산업 발전 방향을 제시할 수 있습니다.

자세히 보기 →

PP/PE 복합 소재에 필러를 추가할 때 호환제를 추가해야 하나요?

PP-g-MAH 호환제의 사용법을 조사하고 싶다면 전문 화학물질 공급업체에 문의하면 샘플과 기술 지원을 받을 수 있습니다. COACE와 상담하면 특정 애플리케이션 요구 사항을 충족하는 맞춤형 믹스를 만들 수 있습니다.

자세히 보기 →

메시지 남기기