Overview of Tube Furnace

A tube furnace is a type of laboratory equipment used for high-temperature applications, featuring a cylindrical heating chamber designed to heat samples uniformly along its length. Commonly used in material processing, chemical analysis, and semiconductor manufacturing, it supports processes like annealing, sintering, and calcination.

Features of Tube Furnace

Uniform Heating: Ensures even temperature distribution throughout the sample.

Cylindrical Design: Facilitates consistent heating by minimizing hot spots.

Temperature Range: Capable of achieving high temperatures suitable for various processes.

Programmable Controls: Allows for precise control over heating cycles and profiles.

Gas Flow Control: Supports controlled atmosphere environments for specific reactions.

Compact and Efficient: Designed for efficient operation with minimal footprint.

(Lab High Temperature Tubular Furnace 1200C 1400C 1700C 1800C Tube Furnace)

Specification of Lab High Temperature Tubular Furnace 1200C 1400C 1700C 1800C Tube Furnace

The Laboratory Heat Tubular Heating system is a precision-engineered heater developed for advanced thermal processing applications in research, commercial, and academic setups. Readily available in optimum temperature level scores of 1200 ° C, 1400 ° C, 1700 ° C, and 1800 ° C, this tube heater supplies flexibility for a vast array of high-temperature experiments, including sintering, annealing, calcination, and material synthesis. The furnace features a robust tubular home heating chamber built from high-purity alumina, quartz, or other refractory products, ensuring resilience and thermal security under extreme conditions. Burner differ by model: 1200 ° C and 1400 ° C devices generally make use of Kanthal or silicon carbide (SiC) burner, while 1700 ° C and 1800 ° C designs utilize molybdenum disilicide (MoSi2) or tungsten aspects for remarkable heat resistance. The heating system tube diameter ranges from 20 mm to 200 mm, with personalized sizes as much as 2000 mm, accommodating varied sample sizes and arrangements. Specific temperature control is accomplished using a programmable PID controller with a 30-segment ramp/soak profile, making it possible for accurate heating prices (0.1 ° C to 20 ° C per minute) and dwell times. An incorporated Kind S (Pt-Rh) or Type B (Rhenium) thermocouple guarantees ± 1 ° C temperature level harmony across the warm zone. Safety functions consist of over-temperature defense, automatic power-off, and an air conditioning follower system to stop overheating. The double-layer steel covering with ceramic fiber insulation reduces warmth loss and enhances power efficiency. Optional gas inlet/outlet ports permit inert or reactive ambience procedures (Ar, N2, H2, and so on), ideal for controlled-environment processes. The heater supports straight or upright orientations and is compatible with vacuum cleaner systems for specialized applications. Power needs vary from 220V single-phase (for lower-temperature versions) to 380V three-phase (for 1700 ° C+ versions). Additional accessories include alumina crucibles, example boats, and thermocouple guards. Made for labs needing trusted high-temperature efficiency, this tubular furnace is extensively utilized in materials science, porcelains, metallurgy, and semiconductor research study. Its modular design simplifies maintenance, while the easy to use interface makes sure smooth procedure. Personalized setups for tube materials, home heating zones, and control systems are readily available to meet certain experimental needs.

(Lab High Temperature Tubular Furnace 1200C 1400C 1700C 1800C Tube Furnace)

Applications of Lab High Temperature Tubular Furnace 1200C 1400C 1700C 1800C Tube Furnace

The Lab High-Temperature Tubular Heating system, readily available in 1200 ° C, 1400 ° C, 1700 ° C, and 1800C setups, is a versatile device designed for precision heating in research study and commercial applications. Its cylindrical style makes it possible for consistent thermal circulation, making it optimal for processes requiring regulated atmospheres and high-temperature security.

In materials scientific research, this heating system is crucial for sintering ceramics and metals, annealing to alleviate inner stresses, and synthesizing innovative materials like carbides and composites. At 1200 ° C, it sustains warm therapy of stainless steel and glass hardening, while 1400 ° C promotes the manufacturing of refractory products such as alumina. Greater temperatures (1700– 1800 ° C) make it possible for the synthesis of ultra-high-temperature porcelains (e.g., zirconia) and carbon-based nanomaterials like graphene.

Chemical research study leverages the furnace for driver testing, pyrolysis, and chemical vapor deposition (CVD). The precise temperature control makes sure efficient decomposition of organic substances or growth of slim films. In semiconductor production, it aids in doping procedures and thermal oxidation to create insulating layers on silicon wafers.

The nanotechnology area depends on the heater for synthesizing and functionalizing nanoparticles, carbon nanotubes, and quantum dots. Its ability to preserve inert or responsive ambiences avoids oxidation during high-temperature procedures. In geology, the heater simulates lava development or mineral stage transitions, aiding in product actions research studies under extreme problems.

Power researchers utilize it to develop and examine elements for gas cells, batteries, and solar batteries, such as sintering strong oxide gas cell electrolytes or calcining cathode products. Ecological laboratories apply it for ash content evaluation and researching toxin disintegration at elevated temperatures.

The heater’s compatibility with quartz, alumina, or ceramic tubes expands its energy across various temperature ranges. Advanced functions like programmable home heating cycles, gas circulation control, and quick cooling alternatives improve reproducibility and safety. With applications covering aerospace, electronic devices, metallurgy, and academic community, this tubular heating system is a foundation of innovation, making it possible for breakthroughs in material resilience, power effectiveness, and nanomaterial development. Its versatility across temperatures and atmospheres makes it vital for laboratories pressing the boundaries of high-temperature science.

Company Introduction

Welcome to Designerstudiostore, your premier source for high-quality industrial furnaces designed to meet the stringent demands of modern manufacturing. Our extensive range includes electric, gas, and oil-fired furnaces tailored for various applications such as heat treatment, forging, and laboratory use. With cutting-edge technology and innovative designs, we ensure energy efficiency and superior performance in every product. At Designerstudiostore, we prioritize customer satisfaction by offering customized solutions, reliable after-sales support, and seamless global delivery options. Explore our catalog and discover why businesses worldwide trust us for their heating needs.

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 Lab High Temperature Tubular Furnace 1200C 1400C 1700C 1800C Tube Furnace

What is the maximum temperature and heating duration of the Lab High Temperature Tubular Furnace? The furnace is available in four models with maximum temperatures of 1200°C, 1400°C, 1700°C, and 1800°C. Operating durations vary based on temperature and model. For continuous use, the 1200°C and 1400°C models can typically run for 24–48 hours, while the 1700°C and 1800°C models are designed for shorter cycles (8–12 hours) to prevent overheating. Always refer to the manufacturer’s guidelines for specific thermal profiles and duty cycles.

What heating elements are used in these tube furnaces? Lower-temperature models (1200°C and 1400°C) use Kanthal wire or silicon carbide heating elements. High-temperature models (1700°C and 1800°C) employ molybdenum disilicide (MoSi2) or ceramic composite elements for superior heat resistance and stability. These materials ensure rapid heating, uniform temperature distribution, and long-term durability under extreme conditions.

What tube materials are compatible with these furnaces? The furnace supports quartz tubes (up to 1200°C), alumina tubes (up to 1700°C), and specialized ceramic or zirconia tubes for 1800°C operations. Tube selection depends on thermal conductivity, chemical inertness, and application requirements. Custom tube materials like stainless steel or refractory metals can be used for specific experiments, provided they align with temperature limits.

What safety features are included? Built-in safeguards include over-temperature protection, automatic power cutoff, and real-time temperature monitoring via PID controllers. Advanced models feature emergency cooling fans, gas flow sensors (for inert atmosphere setups), and reinforced insulation to prevent external casing overheating. Users receive alerts for thermocouple failures or temperature deviations.

What applications are these tube furnaces suited for? These furnaces are ideal for materials research, ceramics sintering, metal annealing, catalyst studies, and semiconductor processing. They support processes like chemical vapor deposition (CVD), pyrolysis, and thermal decomposition. Compatibility with inert or reactive gases makes them versatile for academic labs, industrial R&D, and quality control environments requiring precise high-temperature control.

(Lab High Temperature Tubular Furnace 1200C 1400C 1700C 1800C Tube Furnace)