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Boquilla de carburo de boro
Purity: ≥99.5%
Boron Carbide Nozzle is made from high-purity fine boron carbide powder through high-temperature hot-pressing or pressureless sintering. It is widely used in sandblasting, water jet cutting, high-temperature spraying, and metal surface coating. As a leading supplier and manufacturer of premium boron carbide products, we can supply high-quality boron carbide nozzles with various specifications and competitive prices, offering customized solutions to meet specific requirements.
O envíenos un correo electrónico a sales@heegermaterials.com.Boron Carbide Nozzle Data Sheet
| Purity: | ≥99.5% |
| Apparence: | Black or grey |
| Chemical Formula: | B₄C |
| Density: | 2.46-2.62 g/cm³ |
Boron Carbide Nozzle Description
Boron Carbide is a ceramic material with exceptional hardness close to that of diamond and cubic boron nitride, commonly manufactured through sintering processes. Boron carbide nozzles are made using hot-pressing or pressureless sintering, offering high hardness, wear resistance, and superior high-temperature and corrosion resistance. Their lifespan is three times longer than conventional hard alloys like tungsten carbide and silicon carbide. Advanced Ceramics Hub provides high-precision boron carbide nozzles with consistent quality and minimal size variation, suitable for both large-scale and custom production.
Boron Carbide Nozzle Specifications
| Length (mm) | Outer Diameter (mm) | Inner Diameter (mm) | Length (mm) | Outer Diameter (mm) | Inner Diameter (mm) |
| 35 | 20 | 4 | 60 | 20 | 8 |
| 35 | 20 | 6 | 60 | 20 | 10 |
| 35 | 20 | 8 | 60 | 25 | 10 |
| 35 | 20 | 10 | 80 | 20 | 4 |
| 35 | 20 | 12 | 80 | 20 | 6 |
| 45 | 20 | 6 | 80 | 20 | 8 |
| 45 | 20 | 8 | 80 | 20 | 10 |
| 45 | 15 | 6 | 80 | 20 | 12 |
| 55 | 15 | 6 | 80 | 29 | 10 |
| 55 | 20 | 5 | 80 | 29 | 12 |
| 55 | 20 | 8 | 82 | 21 | 6 |
| 60 | 20 | 6 | 82 | 21 | 8 |
Boron Carbide Nozzle Types
- Straight Hole Nozzle
- Long Venturi Nozzle
- Double Venturi Nozzle
- Angle Nozzle
- Banana Nozzle
- Wet Nozzle
- Inner Tube Nozzle
- Custom Nozzle
Boron Carbide Nozzle Advantages
- High hardness and high strength
- Excellent thermal shock resistance
- Excellent chemical inertness
- Excellent wear resistance
- Good corrosion resistance
- High temperature resistance
- High bending strength
- Light weight
Boron Carbide Nozzle Pressureless Sintering Process
- Raw Material Preparation: Use high-purity boron carbide powder and sintering aids.
- Powder Mixing: Mix powder and sintering aids evenly.
- Molding: Shape the powder into the desired form.
- Degassing: Remove volatile components to avoid bubbles or cracks.
- Pressureless Sintering: Sinter at 1600-2000°C.
- Cooling and Inspection: Cool to room temperature and inspect for quality.
Boron Carbide Nozzle Applications
- Sandblasting: Employed in sandblasting nozzles, withstanding high-speed abrasive impacts for surface cleaning, rust removal, or engraving.
- Waterjet Cutting: Used as core components in waterjet nozzles, enduring high-pressure water and abrasive impacts for precise cutting of metals, ceramics, and more.
- Industrial Coating: Applied in thermal or plasma spraying equipment, resisting high temperatures and chemical corrosion to ensure coating quality.
- Chemical Industry: Utilized in nozzle systems for spraying corrosive liquids or gases, extending service life.
- Agriculture and Firefighting: Used in high-pressure spray systems, such as agricultural irrigation or firefighting, offering durability and a long lifespan.
Boron Carbide Material Properties
Boron Carbide Material Grades
Reaction bonded boron carbide (B4C) is primarily used ballistic armor, providing excellent protection while reducing weight as compared to other armor materials.
| Properties | Units | Reaction Bonded Boron Carbide |
| Flexural Strength, MOR (20 °C) | MPa | 250 |
| Fracture Toughness, KIc | MPa m1/2 | 3.0 – 4.0 |
| Thermal Conductivity (20 °C) | W/m K | 50 |
| Coefficient of Thermal Expansion | 1×10-6/°C | 4.5 |
| Maximum Use Temperature | °C | 1000 |
| Dielectric Strength (6.35mm) | ac-kV/mm | — |
| Dielectric Loss (tan δ) | 1MHz, 25 °C | — |
| Volume Resistivity (25°C) | Ω-cm | 10³ |
Reaction Bonded B4C Advantages:
- High strength
- High hardness
- Cost-effective
- Suitable for large-scale applications
Hot-pressed, also known as pressure assisted densified (PAD), boron carbide is one of the hardest materials available in commercial shapes. This exceptional hardness combined with low density is used in ballistic armor, maximizing protection while minimizing weight.
| Properties | Units | Hot Pressed Boron Carbide |
| Flexural Strength, MOR (20 °C) | MPa | 320 – 450 |
| Fracture Toughness, KIc | MPa m1/2 | 3.0 – 4.0 |
| Thermal Conductivity (20 °C) | W/m K | 45 – 100 |
| Coefficient of Thermal Expansion | 1×10-6/°C | 4.5 – 4.9 |
| Maximum Use Temperature | °C | 2000 |
| Dielectric Strength (6.35mm) | ac-kV/mm | — |
| Dielectric Loss (tan δ) | 1MHz, 25 °C | — |
| Volume Resistivity (25°C) | Ω-cm | 100 |
Hot Pressed B4C Advantages:
- Higher density
- Better mechanical properties
- Ideal for high-strength, high-temperature engineering materials
Pressureless sintered boron carbide combines high purity and the excellent mechanical properties of boron carbide for use in both ballistic armor and semiconductor manufacturing.
| Properties | Units | Sintered Boron Carbide |
| Flexural Strength, MOR (20 °C) | MPa | 450 |
| Fracture Toughness, KIc | MPa m1/2 | 3.0 – 5.0 |
| Thermal Conductivity (20 °C) | W/m K | 43 – 100 |
| Coefficient of Thermal Expansion | 1×10-6/°C | 4.5 – 4.9 |
| Maximum Use Temperature | °C | — |
| Dielectric Strength (6.35mm) | ac-kV/mm | — |
| Dielectric Loss (tan δ) | 1MHz, 25 °C | — |
| Volume Resistivity (25°C) | Ω-cm | 10 |
Pressureless Sintered B4C Advantages:
- High hardness
- Excellent wear resistance
- High chemical stability
- Low density
- Good thermal stability
Boron Carbide Ceramic Machining
Boron Carbide Ceramic machining is a demanding process used to shape this ultra-hard ceramic into precise components for technical applications. Due to its exceptional hardness and brittleness, machining boron carbide requires specialized tools and careful control to prevent cracking or surface damage. While the material can be shaped more easily in its green or biscuit state, achieving tight tolerances often requires machining after full sintering, which involves diamond-based techniques. The common machining methods include:
- Diamond Cutting: Diamond-coated tools are essential for cutting fully sintered boron carbide, enabling accurate shaping and smooth surface finishes.
- Precision Grinding: Used to achieve fine tolerances and clean finishes. This process is slow and requires careful handling to avoid micro-cracks or structural damage.
- Ultrasonic Machining: Applies high-frequency vibrations with abrasive slurry to remove material gently, suitable for intricate and delicate shapes.
- Laser Cutting: A non-contact technique effective for pre-sintered material or thin sections, offering clean edges with minimal thermal stress.
- Green Machining: Carried out before sintering, allowing easier shaping of complex geometries. However, post-sintering shrinkage (~20%) must be accounted for in final dimensions.
Boron Carbide Ceramic Packaging
Boron Carbide ceramic products are typically packaged in vacuum-sealed bags to prevent moisture or contamination and wrapped with foam to cushion vibrations and impacts during transport, ensuring the quality of products in their original condition.
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