Infrared Mold Furnace Highlights And The Advantages And Disadvantages of Infrared Heating

 Infrared mold furnace highlights and advantages and disadvantages of infrared heating

    The heat source of the infrared mold heating furnace uses iron solder aluminum alloy wire. Its features include high efficiency and energy saving. Behind the electric heating wire, there is an infrared radiation plate that effectively reflects heat into the furnace chamber. The radiation plate, electric heating wire, and infrared heating body form a system that radiates heat in the form of electromagnetic energy into the furnace chamber. The mold absorbs this electromagnetic energy and converts it back into thermal energy. The mold frame is designed with a high-temperature resistant stainless steel grid structure, providing excellent mechanical strength as well as good ventilation and light transmission effects.

  Energy saving: 

(1)The reasonable design of drawer-style trays significantly reduces heat loss.

(2)Effective use of heat, with self-developed infrared radiation panels absorbing heat and directly radiating it into the furnace to heat the mold. 

(3)Insulation measures using high-density high-molecular glass fiber materials effectively reduce heat loss, thus achieving direct energy savings. Safe, quick, and comfortable operation: The drawer-style mold placement and removal avoids the discomfort caused by hot air from traditional molds, leading to safer operation and increased work efficiency.

  Efficiency:  The infrared mold heating furnace can heat multiple molds at once, avoiding the situation where there are no hot molds to replace when the mold change frequency is high. It features direct and simple heat transfer, high thermal efficiency in production, hygiene and environmental protection, sterilization and disinfection, quick and clean grilling of food, excellent quality, and good taste, significantly saving energy, simple manufacturing, and easy promotion.

(1) The heat transfer form of far-infrared radiation is the transmission of thermal energy through electromagnetic waves. When far-infrared rays shine on the heated object, a small portion of the rays are reflected back, while the majority penetrate into the heated object. 

 (2) Since far-infrared rays themselves are a form of energy, when the wavelength of emitted far-infrared rays matches the absorption wavelength of the heated object, the molecules or atoms within the heated object absorb the far-infrared energy, causing intense vibrations and leading to 'resonance' among the molecules and atoms. The high-speed friction between the molecules or atoms generates heat, raising their temperature and achieving the heating purpose. Far-infrared thermal radiation produces vibrational excited-state products rather than electronic excited-state products (which cause visible light and flames), almost entirely releasing energy through infrared radiation. This fundamentally avoids energy loss caused by visible light combustion, making it true infrared combustion technology. Therefore, catalytic combustion is the optimal combustion method for fully and effectively utilizing combustion energy, as demonstrated by the infrared mold heating furnace.