Overview of Silicon Carbide Crucible

Silicon carbide (SiC) crucibles are advanced ceramic vessels known for their exceptional thermal conductivity, high strength, and resistance to thermal shock. These crucibles can withstand extreme temperatures up to 1600°C and are highly resistant to chemical attack, making them ideal for melting metals, alloys, and other materials in both laboratory and industrial settings.

Features of Silicon Carbide Crucible

High Thermal Conductivity: Efficient heat transfer ensures uniform heating and rapid temperature changes.

Thermal Shock Resistance: Can endure rapid temperature fluctuations without damage.

Chemical Inertness: Resistant to most acids and alkalis, minimizing contamination.

Temperature Range: Operates effectively at temperatures up to 1600°C.

Mechanical Strength: Extremely durable and strong, even under harsh conditions.

Non-Reactive: Does not react with the materials being processed, preserving sample purity.

Long Service Life: Durable construction ensures extended use and reliability.

(High Temperature Resistant Silicon Carbide Sagger SISIC RSIC Graphite Ceramic Crucible)

Specification of High Temperature Resistant Silicon Carbide Sagger SISIC RSIC Graphite Ceramic Crucible

The Heat Resistant Silicon Carbide Sagger (SISIC/RSIC) is developed for severe warmth applications. It works in settings as much as 1650 ° C. The product combines silicon carbide (SiC) with graphite. This mix makes sure high stamina and heat resistance. Thermal shock resistance is strong. Rapid temperature level modifications create marginal damage. It is excellent for duplicated home heating and cooling down cycles.

The crucible has excellent thermal conductivity. Warm distributes uniformly. This lowers hot spots. Energy efficiency enhances. Operating costs decline. The dense framework resists oxidation. Chemical rust is lessened. Acids, antacid, and molten steels do not deteriorate it easily. Life span extends contrasted to typical ceramics.

Mechanical longevity is high. The material holds up against hefty loads. Abrasion resistance transcends. It takes care of rough handling during industrial procedures. The surface area stays smooth. Contamination risks reduced. Purity degrees remain secure. This is crucial for metallurgy, ceramics, and semiconductor production.

Requirement sizes vary from 50mm to 500mm in size. Customized dimensions are offered. Wall density varies based on application needs. The layout sustains very easy loading and unloading of materials. High-temperature heaters, kilns, and sintering tools utilize it extensively.

Maintenance is easy. Tidy with non-abrasive tools after cooling. Stay clear of unexpected temperature level drops. Store in dry conditions. Moisture exposure is dissuaded. Regular assessments prevent splits. Substitutes are rare because of long-lasting performance.

The product suits labs and commercial settings. It benefits melting, calcination, and heat therapy. Individuals consist of steel factories, battery material manufacturers, and ceramic producers. Compatibility with inert and responsive environments includes flexibility.

Material requirements include over 98% SiC web content. Thickness exceeds 3.0 g/cm ³. Porosity stays below 1%. Compressive stamina surpasses 250 MPa. These metrics guarantee reliability under anxiety.

Worldwide criteria like ISO 9001 accredit production. Quality checks ensure consistency. Each batch undergoes strenuous screening. Defect rates are very little. Lead times depend on order dimension. Bulk acquisitions minimize expenses.

The crucible ships with protective packaging. Damages throughout transit is rare. Technical assistance is offered for usage guidelines. No specialized training is needed. Compatibility with automated systems enhances operations.

(High Temperature Resistant Silicon Carbide Sagger SISIC RSIC Graphite Ceramic Crucible)

Applications of High Temperature Resistant Silicon Carbide Sagger SISIC RSIC Graphite Ceramic Crucible

High-temperature resistant silicon carbide sagger SISIC RSIC graphite ceramic crucibles deal with extreme warmth. These crucibles work in rough conditions. They offer markets such as metallurgy, electronics, porcelains, and semiconductors. The product combines silicon carbide with graphite. This mix ensures thermal security. It stands up to temperature levels approximately 1600 ° C. The framework remains intact under quick heating or cooling. Thermal shock resistance makes them reliable for duplicated usage.

Metallurgical processes melt steels and alloys. Standard crucibles fracture under high warmth. Silicon carbide crucibles last longer. They lower downtime for substitutes. Chemical inertness stops responses with liquified metals. Pureness stays high. Contamination risks drop.

Electronics manufacturing needs accurate product processing. Silicon carbide crucibles expand solitary crystals for semiconductors. They manage harsh atmospheres. High-purity silicon or gallium arsenide remains unpolluted. The crucibles preserve steady problems for regular outcomes.

Ceramic production makes use of these crucibles for firing advanced ceramics. Items like reducing tools or aerospace elements call for precise temperatures. The crucibles disperse warmth equally. Buckling or issues reduce. Energy effectiveness boosts. Warmth transfers rapidly. Handling times reduce.

Semiconductor construction relies upon these crucibles for silicon wafer processing. They endure hostile chemicals. High thermal conductivity guarantees uniform home heating. This prevents hot spots. Product waste reduces. Manufacturing prices lower.

Toughness establishes these crucibles apart. Standard clay or alumina crucibles use much faster. Silicon carbide stands up to abrasion. Mechanical strength remains high under load. Lifespans prolong. Lasting expenses decrease. Upkeep needs lessen.

Chemical laboratories make use of these crucibles for screening corrosive materials. Acid or alkali exposure causes very little damage. Responses remain managed. Safety and security boosts.

The style matches customized applications. Sizes and shapes adjust to details machinery. Customers optimize operations without endangering efficiency. Initial costs may exceed standard options. Savings from resilience and efficiency offset this.

High-temperature silicon carbide crucibles fulfill demanding industrial needs. Performance remains stable in severe conditions. Industries accomplish greater productivity. Item quality improves. Operational dependability grows.

Company Introduction

Welcome to Teen-Hot,a leading global supplier of high-quality crucibles designed for various industrial applications. We offer an extensive range of crucibles, including graphite, ceramic, and metal varieties, tailored to meet the needs of foundries, laboratories, and manufacturers. Our products are renowned for their durability, thermal resistance, and precision engineering, ensuring optimal performance in melting and heat treatment processes. With advanced manufacturing facilities and a commitment to excellence, we provide reliable, cost-effective solutions worldwide. Partner with us for your crucible needs and experience superior quality, expert support, and timely delivery.

If you have any questions, please feel free to contact us(nanotrun@yahoo.com).

Payment Methods

T/T, Western Union, Paypal, Credit Card etc.

Shipment Methods

By air, by sea, by express, as customers request.

5 FAQs of High Temperature Resistant Silicon Carbide Sagger SISIC RSIC Graphite Ceramic Crucible

What materials are High Temperature Resistant Silicon Carbide Saggers made of? These crucibles combine silicon carbide (SISIC or RSIC) with graphite and ceramic. The mix ensures strength and heat resistance. High-purity raw materials prevent contamination during high-temperature processes. This makes them suitable for metal melting, chemical reactions, and lab experiments.

How much heat can these crucibles handle? They withstand up to 1600°C in air and 2200°C in inert environments like argon or vacuum. The material stays stable under extreme heat. It resists thermal shock, meaning sudden temperature changes rarely cause cracks. This reliability suits repeated use in industrial furnaces.

What industries use these crucibles? Common applications include metal foundries, glass manufacturing, and semiconductor production. Labs use them for high-temperature testing. They work in kilns, induction heaters, and sintering furnaces. Their corrosion resistance makes them ideal for melting metals like gold, aluminum, or alloys.

How do these crucibles compare to traditional ones? Clay or alumina crucibles wear out faster under high heat. Silicon carbide lasts longer and handles higher temperatures. This reduces replacement costs and downtime. They also transfer heat more evenly, improving process efficiency. Their mechanical strength resists cracking during handling.

How should users maintain these crucibles? Clean them after each use to remove residue. Avoid sudden cooling after heating. Inspect for cracks or wear before reuse. Store them in dry conditions to prevent moisture damage. Follow manufacturer guidelines for maximum temperature limits. Proper care extends their lifespan significantly.

(High Temperature Resistant Silicon Carbide Sagger SISIC RSIC Graphite Ceramic Crucible)