The far-infrared quartz heating plate uses high-radiation quartz tubes as the base matrix, assembled with electrothermal alloy resistance wire. Thick insulating, refractory and thermal insulation materials are laid at the bottom of the heating elements, covered with a metal outer housing; after wiring installation, the unit is ready for power-on operation. Adopting NanoHeat nano thermal energy technology, it contains no mechanical heating components, supports dry burning operation, and generates zero electromagnetic field interference or radiation hazards. Ultra-fast heating: temperature rises by 5℃ within just 1 second.

High radiation emissivity, high radiant temperature, excellent structural integrity, stable thermal performance, uniform heat distribution, high dielectric strength, long service life, high electrothermal conversion efficiency, fast temperature ramp, low thermal inertia, high temperature resistance, corrosion resistance, stable thermochemical properties, zero pollution and simple installation. Compared with conventional electric heating elements, it achieves approximately 30% energy saving, making it a new generation energy-saving heating component.

Quartz Glass Material Advantages: Softening point around 1730℃; continuous long-term working temperature up to 1100℃, short-term peak temperature up to 1450℃. Exceptional corrosion resistance: inert to nearly all acids except hydrofluoric acid. Acid resistance is 30 times that of ceramics and 150 times that of stainless steel; its high-temperature chemical stability is unmatched by any other engineering material.

Additional merits: high technical content, clean & hygienic, easy assembly, acid & corrosion resistant, extended service life. Blackbody ceramic infrared heating plates are widely used in vacuum plastic forming, food baking and all infrared drying, baking & curing processes, delivering remarkable energy-saving benefits for electronics, textiles, light industry, electromechanical chemical and food sectors with prominent economic & social benefits. Custom processing available per unique customer specifications.

The far-infrared quartz heater core consists of high-strength quartz tubes with spiral resistance wires embedded inside precision-processed milky pure quartz glass tubes, featuring moderate heating speed, mild luminous brightness and long service lifespan.

1. Diversified operation modes compatible with various lab experiment requirements
2. Ultra-precise temperature control accuracy up to ±0.1℃
3. Temperature hold setting adjustable in 1℃ increments
4. Split modular design for heating module & control unit, equipped with intelligent PID control system
5. Multiple heating & constant temperature mode options for flexible selection
6. Powered by proprietary NanoHeat technology: 5℃ temperature rise in 1 second, full ramp to 450℃ within only 8 minutes
7. Zero mechanical heating components, no electromagnetic interference, ideal for medical and laboratory environments
8. Low power standby state, power consumption less than 1W
9. Compatible with most lab vessels: glass, ceramic and metal containers
10. User-friendly infrared hot plate: physical control buttons, digital display, safety lock, timer function and high-temperature alarm indicator for convenient operation
11. Elegant, sleek and premium exterior design
12. Corrosion-resistant microcrystalline ceramic top layer for effortless daily cleaning

Widely deployed in experimental and analytical laboratories for agriculture, soil testing, environmental monitoring, food safety research, research institutes and universities. Suitable for sample heating, baking, digestion and post-digestion acid removal workflows.

Nano thermal energy technology eliminates mechanical heating parts, supports dry burning without EM radiation. Ultra-fast ramp boosts overall lab processing efficiency: +5℃ in 1s, maximum 450℃ reached in 8 minutes.

1. Heating surface material: Microcrystalline ceramic (Schott, Germany)
2. Heating principle: NanoHeat nano thermal technology (no mechanical heating elements)
3. Power supply: 220–240V AC, 50/60Hz
4. Rated output power: 1500W
5. Overall product dimension: 340(L) × 240(W) × 30(H) mm
6. Effective heating zone: 300(L) × 200(W) mm
7. Temperature control range: Ambient temperature ~ 450℃
8. Temperature control precision: ±1℃
9. Temperature measurement accuracy: ±0.1℃
10. Control system: Split intelligent PID program control; red high-temperature warning light at 40℃, yellow indicator when target temperature is reached
11. Timing range: 1 minute ~ 24 hours

Alternative names: Far-infrared heater, far infrared electric heater, infrared heating plate, infrared electric heating plate.

Infrared ray is one type of invisible light in sunlight, discovered by British astronomer William Herschel in 1800, also known as infrared thermal radiation. He split sunlight via prism and placed thermometers at each color band to test heating effect, finding the thermometer beyond red light showed the fastest temperature rise.

1. Objects with different physical properties emit infrared rays of distinct wavelengths; infrared radiation is preferentially absorbed by substances of matching properties — solid-emitted infrared is easily absorbed by solids, poorly absorbed by gases.
2. Three forms of heat transfer: radiation, conduction, convection.
3. At high temperatures, approximately 90% heat transfers via radiation; radiant intensity is proportional to the fourth power of absolute temperature.
4. Absorption capacity of radiant heat is proportional to the surface emissivity (blackness) of the heated object.
5. Heat conduction intensity inside heated objects is proportional to internal temperature gradient and inversely proportional to thermal resistance.

1. Objects with different physical properties emit infrared rays of distinct wavelengths; infrared radiation is preferentially absorbed by substances of matching properties — solid-emitted infrared is easily absorbed by solids, poorly absorbed by gases.
2. Three forms of heat transfer: radiation, conduction, convection.
3. At high temperatures, approximately 90% heat transfers via radiation; radiant intensity is proportional to the fourth power of absolute temperature.
4. Absorption capacity of radiant heat is proportional to the surface emissivity (blackness) of the heated object.
5. Heat conduction intensity inside heated objects is proportional to internal temperature gradient and inversely proportional to thermal resistance.