Energy saving | 25~55% compared to conventional LNG gas |
Improvement of
environmental safety | Prevention of fire risk caused by LNG direct fire method |
Improvement of
working environment | Improvement of operator's working environment at the entrance/exit of dryer furnace with internal atmospheric temperature of around 40℃ |
Quality improvement | Fundamental improvement of defects caused by foreign matter (reduction of fine dust) with no circulation The characteristics of far-infrared rays, which have a longer wavelength compared to visible rays, penetrate deeply and are dried with simultaneous internal and external heating. |
Productivity
improvement | Heat is transferred in the form of a radiant wave that does not require a medium, so only the material subject to drying is directly heated to shorten the drying time. |
Greenhouse gas
reduction | Reduces CO₂ by 31% compared to LNG method-Introduced as an excellent reduction example by the Korea Energy Agency |
Reduces
maintenance costs | No special peripheral devices required. With simple structures, the technology improves maintenance costs by 80% compared to the hot air method |
Energy saving | 25~55% compared to conventional LNG gas |
Improvement of
environmental safety | Prevention of fire risk caused by LNG direct fire method |
Improvement of
working environment | Improvement of operator's working environment at the entrance/exit of dryer furnace with internal atmospheric temperature of around 40℃ |
Quality improvement | Fundamental improvement of defects caused by foreign matter (reduction of fine dust) with no circulation The characteristics of far-infrared rays, which have a longer wavelength compared to visible rays, penetrate deeply and are dried with simultaneous internal and external heating. |
Productivity
improvement | Heat is transferred in the form of a radiant wave that does not require a medium, so only the material subject to drying is directly heated to shorten the drying time. |
Greenhouse gas
reduction | Reduces CO₂ by 31% compared to LNG method-Introduced as an excellent reduction example by the Korea Energy Agency |
Reduces
maintenance costs | No special peripheral devices required. With simple structures, the technology improves maintenance costs by 80% compared to the hot air method |
The water evaporation speed in the drying process is heavily dependent on the type or shape of the object, and technology optimization is difficult considering the characteristics of heat transfer (conduction, convection, and radiation) from the constituent heat facilities, including heaters, to the object.
→ Development of optimal electric heating devices according to the object to be heated
Standardization and normalization of heat facility specifications for high efficiency/precise control are difficult as conditions of dry heating are very diverse.
→ Development of high-performance (high output/ high sensitivity/ high efficiency) industrial heating and drying equipment
→ Development of cutting-edge industrial infrared drying wave guide heating devices for uniforme drying of complex-shaped structures
→ Technology for optimizing exhaust gas discharge flow convection
Since it is difficult to perform facility verification at the pilot stage, the barrier to entry to a large-scale demonstration facility is huge, and high efficiency of dryers mostly leads to a large increase in initial investment costs. Therefore, it is necessary to verify the feasibility of early investment cost recovery due to improved efficiency.
→ Applied to mass production line of automobiles and heavy equipment (the first in the world) to secure verification data on the feasibility of recovering initial investment costs by improving efficiency
→ Two years ROI based on heavy equipment
→ Technology development to ensure durability of mechanical and electrical materials in high-temperature thermal cycles
Since industrial dryers are large and consume a lot of energy, they are difficult to apply to the production line on a pilot basis for performance evaluation of the efficiency-improving prototype. It is also difficult to secure suitable test objects.
→ Company H’s vehicle body was rented and drying setting completed after testing for three months.
→ Completion of pilot testing for heavy equipment products and securing installation performance (energy cost reduction of 50% or more)
CEO : Cho So-angㅣ Corporate registration No. : 606–86-20638
Location : 31 Noksansandan 362-ro, Gangseo-gu, Busan, S. Korea
Tel : +82-51-831-5071 | Fax : +82-51-831-5072
E-mail : 333tech@naver.com
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