CATEGORIES

    Infrared Oven

    Overview Products Knowledge Standards Terms
    Infrared ovens use infrared radiation to directly heat the surface of objects without the need for a medium to transfer heat. They generate thermal energy by causing molecular vibrations in materials through electromagnetic waves, making them suitable for rapid drying of coatings, curing inks, and processing samples. In industries such as coatings and plastics, they are used to accelerate moisture evaporation and material curing processes.
    Selection
    When selecting an infrared oven, considerations include matching the material's absorption characteristics with the radiation wavelength, ensuring temperature control precision meets process requirements, aligning the chamber size with sample specifications, balancing energy consumption with production efficiency, ensuring the operation interface aligns with user habits, and balancing maintenance costs with equipment lifespan.
    Style
    Product Type
    Principle
    Airflow Direction
    Temp Range
    temperature resolution
    volume
    Heater Type
    Chamber Material
    Temp Fluctuation
    Temp Uniformity
    Safety Protection

    Terms

    Thermal Imager
    Infrared Spectrometer
    Scanning Infrared Thermometer
    Monochromatic Infrared Thermometer
    Far-infrared thermal imager
    Infrared Thermal Imager
    Irradiance meter
    Six-channel furnace temperature tracker
    High-temperature infrared thermometer
    Infrared Thermal Imager

    Standards

    Active GB/T 25929-2010
    Specification of infrared gas analyzers
    Active GB/T 24131.1-2018
    Rubber, raw—Determination of volatile matter content—Part 1:Hot-mill method and oven method
    Active GB/T 29250-2012
    Far infrared ovens
    Active GB/T 12604.9-2021
    Non-destructive testing—Terminology—Infrared thermography
    Active GB/T 43413-2023
    Non-destructive testing—Infrared thermographic testing—General principles for thermoelastic stress measuring method
    Active GB/T 45166-2024
    Non-destructive testing—Infrared thermographic testing—General principles
    Active GB/T 20216-2016
    Pulp and paper—Determination of the effective residual ink concentration (ERIC number)—Infrared reflectance measurement
    Active GB/T 22906.3-2008
    Testing of cores - Part 3: Determination of moisture content using the oven drying method
    Active GB/T 30648.5-2015
    Paints and varnishes—Determination of resistance to liquids—Part 5: Temperature-gradient oven methods
    Active GB/T 4653-1984
    The general technical specifications on infrared radiation paints

    Instruments

    BOZHEN 766-3A Far infrared fast Drying Oven Automatic thermostatic Drying Oven
    BOZHEN 766-3A Far infrared fast Drying Oven Automatic thermostatic Drying Oven

    Far infrared radiation heating technology, temperature control accuracy +/- 2 ℃, equipped with thermistor control thermoMeter, rapid low consumption drying, Inner Chamber dimensions 320 * 380 * 320mm.

    $ 391.00
    BOZHEN 766-1A Far infrared fast Drying Oven Automatic thermostatic Drying Oven
    BOZHEN 766-1A Far infrared fast Drying Oven Automatic thermostatic Drying Oven

    Far infrared radiation heating technology, Temperature range RT +~ 300 ℃, Temperature Fluctuation +/- 2 ℃, equipped with thermistor control thermoMeter, fast low consumption adjustment is convenient.

    $ 507.00
    BOZHEN 766-2A Far infrared fast Drying Oven Automatic thermostatic Drying Oven
    BOZHEN 766-2A Far infrared fast Drying Oven Automatic thermostatic Drying Oven

    Far infrared radiation heating technology, Temperature range RT +~ 300 ℃, temperature fluctuation +/- 2 ℃, equipped with thermistor control thermoMeter, with fast, low consumption, easy adjustment and other advantages, suitable for drying a variety of samples.

    $ 465.00
    BOZHEN 766-0A Far infrared fast Drying Oven Automatic thermostatic Drying Oven
    BOZHEN 766-0A Far infrared fast Drying Oven Automatic thermostatic Drying Oven

    Far infrared radiation heating technology, equipped with thermistor control thermoMeter, Temperature range RT +~ 300 ℃, Temperature Fluctuation +/- 2 ℃, with fast drying and low energy consumption characteristics, suitable for a variety of Sample Handling.

    $ 586.00
    TQC sheen AB8000 Oven CureView Gradient Oven infrared halogen heater
    TQC sheen AB8000 Oven CureView Gradient Oven infrared halogen heater

    32 infrared halogen heaters, temperature range RT + 5~ 350 ℃, can be set parabolic layer or rising slope, the maximum test plate size 570mm, support the intRoduction layer Linear dispersion simulation pRoduction process.

    $ 108363.00
    BOZHEN 766-2AS digital display stainless steel liner Far infrared Drying Oven 304 stainless steel liner
    BOZHEN 766-2AS digital display stainless steel liner Far infrared Drying Oven 304 stainless steel liner

    Far infrared radiation heating technology, Temperature range RT +~ 300 ℃, Temperature Fluctuation +/- 2 ℃, equipped with stainless steel liner, rapid and uniform heating, suitable for drying a variety of samples.

    $ 690.00
    BOZHEN 766-0AS Linear dispersion temperature control Far infrared Drying Oven Stainless steel studio rapid drying
    BOZHEN 766-0AS Linear dispersion temperature control Far infrared Drying Oven Stainless steel studio rapid drying

    Far infrared radiation heating technology, Temperature range RT +~ 300 ℃, Temperature Fluctuation +/- 2 ℃, equipped with thermistor control thermoMeter, rapid low consumption drying, suitable for a variety of Sample Handling.

    $ 1009.00
    BOZHEN 766-1AS Digital display stainless steel liner Far infrared Drying Oven 304 stainless steel liner RT +~ 300 ℃
    BOZHEN 766-1AS Digital display stainless steel liner Far infrared Drying Oven 304 stainless steel liner RT +~ 300 ℃

    Far infrared radiation heating technology, Temperature range RT +~ 300 ℃, Temperature Fluctuation +/- 2 ℃, equipped with thermistor temperature control, fast low consumption, suitable for a variety of sample drying.

    $ 756.00
    BOZHEN 766-2AS Linear dispersion temperature control Far infrared Drying Oven Automatic thermostatic fast drying
    BOZHEN 766-2AS Linear dispersion temperature control Far infrared Drying Oven Automatic thermostatic fast drying

    Far infrared radiation heating technology, Temperature range RT +~ 300 ℃, Temperature Fluctuation +/- 2 ℃, equipped with thermistor control thermoMeter, automatic thermostatic control, fast drying and low energy consumption.

    $ 883.00
    QIWEI WS70-1 Drying Oven Infrared fast Drying Oven 550W metal material
    QIWEI WS70-1 Drying Oven Infrared fast Drying Oven 550W metal material

    Infrared heat source for fast drying, Power 550W, metal material to ensure durability, built-in heating element to pRoduce uniform heat cycle, effective evaporation of water, suitable for drying various materials.

    $ 159.00
    BOZHEN 766-3AS Linear dispersion temperature control Far infrared Drying Oven Fast and low consumption Automatic thermostatic
    BOZHEN 766-3AS Linear dispersion temperature control Far infrared Drying Oven Fast and low consumption Automatic thermostatic

    Far infrared radiation heating technology, Temperature range RT +~ 300 ℃, Temperature Fluctuation +/- 2 ℃, equipped with thermistor temperature control system, the studio is made of 304 stainless steel for fast and uniform heating.

    $ 775.00
    BOZHEN 766-1AS Linear dispersion temperature control Far infrared Drying Oven Automatic thermostatic fast drying
    BOZHEN 766-1AS Linear dispersion temperature control Far infrared Drying Oven Automatic thermostatic fast drying

    Far infrared radiation heating technology, Temperature range RT +~ 300 ℃, Temperature Fluctuation +/- 2 ℃, equipped with thermistor temperature control system to achieve automatic thermostatic operation, the studio is made of 304 stainless steel, size 600 * 600 * 500mm.

    $ 932.00
    HEIGHT-LED HTBX-II Large UVLED Curing Oven No Infrared Radiation Cold Illuminant
    HEIGHT-LED HTBX-II Large UVLED Curing Oven No Infrared Radiation Cold Illuminant

    LED Cold Illuminant Technology, No Infrared Radiation, Suitable for Heat Sensitive Materials; Power density 400-2400mw/cm ², curing area 500x400mm.

    $ 5282.00
    BOZHEN 766-3AS digital display stainless steel liner Far infrared Drying Oven 304 stainless steel liner RT +~ 300 ℃ temperature control
    BOZHEN 766-3AS digital display stainless steel liner Far infrared Drying Oven 304 stainless steel liner RT +~ 300 ℃ temperature control

    Far infrared radiation heating technology, Temperature range RT +~ 300 ℃, Temperature Fluctuation +/- 2 ℃, equipped with thermistor control thermoMeter, with fast drying, low energy consumption and easy adjustment, suitable for a variety of Sample Handling.

    $ 581.00
    BOZHEN 766-0AS Digital display stainless steel liner Far infrared Drying Oven Fast and low consumption Automatic thermostatic
    BOZHEN 766-0AS Digital display stainless steel liner Far infrared Drying Oven Fast and low consumption Automatic thermostatic

    Far infrared radiation heating technology, temperature control accuracy +/- 2 ℃, fast and low consumption, equipped with thermistor temperature control, the studio is made of 304 stainless steel, size 750 * 600 * 600mm, easy to adjust, suitable for drying treatment of various samples.

    $ 840.00

    Articles

    The use of gravure proofing machines in the comprehensive evaluation of gravure ink printability and drying performance.
    This article explores how a gravure proofing press can be used to comprehensively evaluate the printability and drying properties of gravure inks. The experiment tested the dot sharpness, transfer rate, and leveling properties of different inks using standard equipment, while recording drying times through the filter paper method and infrared temperature measurement.
    Research on the Stepwise Curing Process of Coatings Using Multi-Stage Temperature Control Ovens
    This article investigates a novel process for achieving stepwise curing of coatings using a multi-stage temperature-controlled oven.
    UV-Vis-NIR spectrophotometer measures the transmittance of anti-reflection coatings.
    This article introduces the method of measuring the transmittance of anti-reflective coatings using a UV-Vis-NIR spectrophotometer. The instrument is based on the Beer-Lambert law, calculating transmittance by comparing the light intensity of the sample and the reference, covering a wide spectral range from ultraviolet to near-infrared.
    Performance Comparison of Electrochemical Sensors and Infrared Sensors in Multi-Gas Detectors
    This article compares the performance of electrochemical sensors and infrared sensors in multi-gas detectors.
    Evaluation of thermal aging life of hot melt adhesives using high-temperature oven method
    This article introduces a method for evaluating the thermal aging life of hot melt adhesives using a high-temperature oven. The principle is based on the Arrhenius equation, where aging is accelerated by increasing the temperature to simulate performance changes under long-term use.
    Thermogravimetric Analyzer for Determining the Solid Content of Coatings
    Thermogravimetric analyzers determine the solid content of coatings by monitoring the change in sample mass with temperature, offering faster and more precise results compared to traditional oven methods.
    Xenon lamp aging test chamber for testing coating weatherability.
    Xenon lamp aging test chambers accelerate the testing of weather resistance for materials such as coatings in the laboratory by simulating the ultraviolet, visible, and infrared portions of sunlight, while controlling conditions like temperature, humidity, and water spray.
    What is the deviation between the moisture meter's rapid moisture measurement and the oven method?
    This article primarily compares the differences between rapid moisture analyzers and traditional oven methods in measuring moisture. Understanding these differences helps in using rapid moisture analyzers more appropriately, ensuring data reliability while maintaining efficiency.
    Key Technical Points for Determining Paper Moisture Using the 105℃ Oven Method
    This article introduces the specific procedure for measuring paper moisture using the 105°C oven method. The process involves placing paper samples into a 105°C oven and drying them until their weight remains constant, then calculating the moisture content based on the weight difference before and after drying.
    Oven combined with analytical balance for determination of solid content
    This article introduces a method for determining the solid content of samples in the laboratory by combining an oven and an analytical balance.
    Temperature gradient control in high-temperature ovens during thermal resistance testing.
    The heat resistance test simulates the performance of materials under high temperatures using a high-temperature oven, and the accuracy of its results is highly dependent on the uniformity of temperature inside the oven. If the temperature gradient is poorly controlled, it can lead to uneven heating of samples from the same batch, compromising the validity of the test.
    What are the differences between a vacuum oven and a conventional oven?
    The main difference between a vacuum oven and a conventional oven lies in their working pressure. Conventional ovens operate at atmospheric pressure, heating through air convection, making them suitable for routine drying tasks. In contrast, vacuum ovens are evacuated to low pressure to reduce air presence, primarily relying on thermal radiation for heat transfer. This makes them ideal for processing heat-sensitive, oxidation-prone materials or those requiring thorough drying.
    Natural Convection vs Forced Air Drying: What’s the Difference Between the Two "Schools" of Laboratory Ovens?
    This article introduces two drying methods for laboratory ovens: natural convection and forced air drying. What are the differences between them?
    How to Choose the Right Spectrophotometer
    When selecting a spectrophotometer, it is essential to start from the actual analytical needs, clearly defining the required wavelength range (ultraviolet, visible, or infrared) and the type of detection. Key evaluations should focus on core specifications of the optical system, such as wavelength accuracy, beam type, and stray light levels.