GSL-1600X is a Vacuum Tube type high temperature tube furnace.
Our Vacuum Tube Furnace uses a silicon molybdenum rod as a heating element.
The rated temperature of the battery tube furnace is 1500℃.
The Battery Tube furnace 's range of use is greatly improved due to its ability to operate in different atmospheres.
The High Temperature furnace has advantages such as high-temperature capability, precise temperature control, simplicity of operation, and convenient maintenance.
GSL-1600X vacuum tube type high temperature tube furnace with silicon molybdenum rod as a heating element, rated temperature 1500℃, using B-type double platinum-rhodium thermocouple temperature measurement 518P automatic temperature control instrument, with high-temperature control accuracy (±1℃). In addition, the furnace has a vacuum device, that can work in a variety of atmospheres, greatly improving its range of use. The vacuum tube furnace has the advantages of high temperature, high precision temperature control, simple operation, convenient maintenance, etc. It can be widely used in metallurgy, machinery, light industry, commodity inspection, colleges and universities, and scientific research departments.
Basic Parameters:
Product Name
AOT-GSL-1600X Battery tube furnace
Main parameter
1. Maximum temperature: 1600℃ (<30min)
2. Long-term operating temperature: 800-1500℃
3.Recommended heating rate: below 1400℃ : ≤10℃/min; 1400 ° C to 1600 ° C: ≤5 ° C /min
4. Length of heating zone: 290mm
5. Maximum power: 5.2 KW
6. Voltage: single-phase AC220V 50Hz
Furnace structure
1. Double shell structure, with air cooling system, so that the surface temperature of the shell is less than 55℃.
2. The tube furnace adopts high-purity polycrystalline alumina fiber to minimize energy loss.
3. The surface of the inner tube furnace is coated with an aluminum oxide coating of 1750 degrees imported from the United States, which
Can improve the reflectivity and heating efficiency of the equipment, but also can extend the service life of the instrument.
Furnace tube
(Standard) OD: 60 mm x 1000 mm L
To ensure the uniformity of the temperature field and the tightness of the flange, the alumina tube plug should be
plugged into both ends of the tube furnace tube before the instrument is used to heat up to prevent the loss of heat.
Vacuum seal
Standard with two stainless steel vacuum flanges (mechanical pressure gauge and stainless steel stop valve installed above).
Vacuum degree
The vacuum degree can reach 10-3 torr with the double rotary vane mechanical pump.
If you want a higher vacuum (<10-5 torr or better).
Temperature control system
PID30 segment programmed automatic control.
Temperature control accuracy: ±1 ℃
Heating element
1750ºC grade silicon molybdenum rod.
Overall dimension
1350 L*520 W*780 H mm
Net weight
150 Kg
Warranty
One-year warranty, lifetime technical support.
Product Display
AOT-GSL-1600X: Vacuum Type High-Temperature Tube Furnace
Temperature measurement is done using a B-type double platinum-rhodium thermocouple and a 518P automatic temperature control instrument.
Vacuum Tube Furnace
The High temperature tube furnace can be widely utilized in industries such as metallurgy, machinery, light industry, and commodity inspection, as well as in colleges, universities, and scientific research departments.
Exhibition
Certificate
FAQ
Q1: How does a battery tube furnace work?
A tube furnace works by utilizing heating elements, usually made of materials like silicon molybdenum rods, to generate heat. The furnace consists of a cylindrical chamber or tube where the sample or material to be heated is placed. The heating elements, often located on the outside of the tube, heat the chamber uniformly.
Q2: What is the heating temperature in the battery tube furnace of the thermal cracking process?
In the thermal cracking process, the heating temperature in a tube furnace typically varies depending on the specific requirements of the process. It can range from several hundred degrees Celsius to over a thousand degrees Celsius. The exact temperature is determined by factors such as the desired reaction kinetics, the type of feedstock being cracked, and the desired product yield. The heating temperature is carefully controlled and maintained within the furnace to ensure efficient and controlled cracking of the feedstock.
Q3: How to use a vacuum tube furnace?
To use a battery tube furnace:
1. Preparation: Ensure the tube furnace is properly connected to a power source and any necessary gas or vacuum supply.
2. Loading: Open the furnace and carefully place the sample or material to be heated inside the tube or chamber.
3. Setting parameters: Set the desired temperature of the furnace using the temperature control panel or interface. Adjust any additional parameters such as heating rate, holding time, or gas flow rate if applicable.
4. Starting the heating process: Close the furnace and initiate the heating cycle by activating the power supply. The heating elements inside the furnace will gradually increase the temperature to reach the desired level.
5. Monitoring: Continuously monitor the temperature using the built-in temperature control instrument or an external thermometer.
6. Cooling: Once the desired heating process is complete, gradually decrease the temperature or turn off the power supply to initiate the cooling process.
7. Unloading: After the furnace has cooled down to a safe temperature, open it and carefully remove the sample or material.
8. Maintenance: Clean the furnace chamber and ensure it is in proper condition for future use.
Q4: How can furnaces be applied to battery production for the battery tube furnace?
Electrode Materials Preparation: Furnaces are used to heat treat and activate electrode materials such as cathodes and anodes. The materials are coated onto current collectors and then heated in the furnace to optimize their structure and properties for improved battery performance.
Sintering: Battery Tube Furnaces are used for sintering processes, where the active materials in the electrodes are fused together to create a cohesive structure. This enhances the conductivity and stability of the electrodes. etc.
