1、硅烷偶联剂 JH

用于聚乙烯交联制造电线、电缆绝缘和护层材料 本品是交联聚乙烯的重要交联剂，其交联工艺与通用的过氧化物交联、辐射交联相比，具有设备简单、投资少、易于控制、应用于聚乙烯密度范围宽、适于生产特殊形状的扇形线芯，并有挤出速度高等特点。 由于硅烷交联聚乙烯具有优异的电气性能，良好的耐热性能及耐应力开裂性能，故本品被广泛应用于制造电线、绝缘和护套材料。 用于聚乙烯交联制造耐热管材、软管及薄膜 由本品作交联剂制得的交联聚乙烯具有良好的耐芳烃、耐油、耐应力开裂、机械强度高、耐热性好等优点，能在80℃下使用50年。 可用于石油长输管道、天然气、煤气管道的防腐保温外防护层及与之配套的防腐保温热收缩套补口材料；可用于民用住宅 …

2、Silane coupling Agent KH‐171

KH‐171 silane, vinyltrimethoxysiane, is used as a polymer modifier via grafting reactions. The resulting pendant trimethoxysilyl groups can function as moisture‐activated crosslinking sites.

3、Silquest™ A

A monomeric vinyl functional silane in vinyl acrylic and acrylic resins, Silquest A-171 silane can be added as a monomer during emulsion polymerization to form silane-modified latexes. Functioning as a crosslinker, the silane in these latexes forms very stable Si-O-Si linkages.

4、Application of Silane Coupling Agent A

Silane Coupling Agent A-171 is a reactive silane coupling agent, suitable for various complex shapes and all densities of polyethylene and copolymers, and suitable for larger processing latitude, filled composite materials, etc.

5、A

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Silane Coupling Agent A

Silane Coupling Agent A-171 - 实际用途 用于聚乙烯交联制造电线、电缆绝缘和护层材料 本品是交联聚乙烯的重要交联剂，其交联工艺与通用的过氧化物交联、辐射交联相比，具有设备简单、投资少、易于控制、应用于聚乙烯密度范围宽、适于生产特殊形状的 ...

Chenguang KH

Chenguang KH-171 is an epoxy-functional silane coupling agent that enhances interfacial bonding between resins (epoxy, acrylic) and inorganic fillers/glass fibers. It improves wet adhesion (>90% retention), mechanical strength, and chemical resistance in composites through siloxane crosslinking.

silane coupling agent KH

Our main products are Amino Silane,Acyloxy silane, Epoxy silane, and Ureido silane, which are widely used in the manufacturing of silicone fluid &sealant, engineered quartz and coating industry.

Silquest A

This increased reactivity makes Silquest A-171 silane one of the fastest hydrolyzing alkoxy silanes available. The elevated rate of hydrolysis is sufficient to enable Silquest A-171 silane to be utilized as a moisture scavenging agent in moisture sensitive systems.

Silane Coupling Agent a

In addition to pursuing continuous progress in technology, we also adhere to the people-oriented concept and strive to improve the quality of Silane Coupling Agent a-171 to a new level.

In chemical production, silane coupling agent 171, as an important chemical reagent, is widely used for surface treatment and modification of various materials. under specific conditions, this seemingly ordinary chemical substance can trigger an unexpected explosion. This not only poses a significant threat to the safety of on-site personnel but also causes severe environmental damage. This article will explore in detail the causes, processes, and countermeasures of the silane coupling agent 171 explosion, aiming to provide references and lessons for future safety management.

I. Causes of the Explosion of Silane Coupling Agent 171

The root cause of the explosion lies in the energy release during the chemical reaction. Under specific temperatures and pressures, silane coupling agent 171 reacts violently with oxygen, moisture, and other media. This reaction releases substantial heat, causing a rapid temperature rise that ultimately leads to an explosion.

II. Process of the Explosion of Silane Coupling Agent 171

1. Reaction Initiation: When silane coupling agent 171 mixes with air or other flammable gases, a series of physical and chemical reactions occur under certain temperature and pressure conditions. These reactions typically include redox reactions, decomposition reactions, and polymerization reactions.

2. Energy Release: As the reaction progresses, interactions between reactants intensify, releasing significant amounts of energy. This energy primarily manifests as heat, causing the temperature within the reaction system to surge.

3. Explosion Occurrence: When the temperature in the reaction system reaches a critical threshold, an explosion is triggered. This is often accompanied by intense shockwaves, flames, and high temperatures, posing grave risks to surrounding environments and personnel.

III. Countermeasures for the Explosion of Silane Coupling Agent 171

1. Preventive Measures: To prevent explosions, stringent control measures must be implemented from the outset. This includes strict quality control of raw materials, storage, and usage conditions; avoiding contact with flammable or explosive substances; and strengthening equipment maintenance and inspections.

2. Emergency Response: In the event of an explosion, on-site personnel must act immediately. This involves evacuating hazardous areas, shutting down valves, cutting off power supplies to prevent fire spread and secondary explosions, and promptly contacting firefighting and rescue services.

3. Post-Incident Handling: After an explosion, a thorough investigation is required to identify causes and responsibilities. Damaged equipment and facilities should be repaired or replaced. Additionally, enhanced safety training and education for employees are critical to improving their safety awareness and responsiveness.

The explosion of silane coupling agent 171 is a common safety accident in chemical production. Analyzing its causes, processes, and countermeasures highlights the need for multifaceted efforts to prevent such incidents. First, raw material quality and usage conditions must be rigorously controlled to avoid contact with flammable substances. Second, equipment maintenance and inspections must be strengthened to eliminate hidden risks. Finally, comprehensive safety training for employees is essential to enhance their awareness and preparedness. Only through these measures can similar accidents be effectively prevented, ensuring the safety of lives and property.