Refrigeration Compressed Air Dryer Buran Ultrapulse
There is more to compressed air than just compressing air Compressed air is an indispensable source of operating and processing power in all areas of industrial and technical production. To prevent production downtimes compressed air must be clean, dry and oil free. Compressed air is generated by raising the pressure of large volumes of ambient air. Usually this air contains harmful substances, such as dirt particles and moisture in the form of water vapour. The water vapour condenses and can lead to operational breakdowns and considerable but avoidable costs. The important advantages of this heat exchanger: Generously sized air-to-air and refrigerant-to-air heat exchanger with a large power density Integral condensate separation system Self-cleaning due to generously dimensioned flow channels Low differential pressure Corrosion resistant aluminium / stainless steel construction How the Buran functions? Compressed air entering the dryer is precooled in the air-to-air heat exchanger by the outgoing cold compressed air. The precooled air then passes through the refrigerant-to-air heat exchanger where it is further cooled to the required pressure dewpoint. The moisture in the compressed air condenses out and is collected and discharged automatically. Finally, the cold discharged air is rewarmed by the incoming compressed air. This saves energy and prevents moisture from forming beyond the dryer in the compressed air system. Condensate separator Air/Air heat exchanger Refrigerant/Air heat exchanger Condensate draining Air outlet approx. 2 C Air inlet approx. C Refrigerant Insulation Water droplets
Intelligence: Buran Ultrapulse 2 3 9 4 5 7 SD 000 AP Buran Refrigeration Compressed Air Dryer 2 3 4 Ultrapulse Compressed-air inlet Compressed-air outlet Condensate separator 7 9 Refrigerant condenser Hemetically sealed refrigerant compressor Refrigerant-to-air heat exchanger Air-to-air heat exchanger 5 Condensate drain
Ultrapulse: State of the art in fridge dryer regulation This microprocessor-based control device is the heart of this generation of fridge dryers. By monitoring parameters such as cooling temperature, pressure in the fridge circuit as well as dryer specific parameters, the actual operational condition of the dryer is calculated. If indicated by the measured data, the fridge compressor will be shut off for a pre-calculated period. The pulsating measuring of the temperature (several times per second) and the use of the aluminium heat exchanger as a storage mass ensures a quick response to load changes without risking dewpoint spikes above the set level. In addition, the processor controls monitors the condensate drain which works without loss of compressed air. Important advantages of the dryer generation Ultrapulse-controlling from SD 000 AP as standard Multi Functional Display load controlled energy consumption, reduction down to 0% of nominal energy consumption load controlled drain low voltage monitoring Display is changeable from C to F Optional: dry contact for alarm signal and analogue signal 0-0 V for dewpoint temperature High operation parameters Environmentally friendly refrigerant R-34a Compact and easy to install cabinets Microprocessor based control device The Multi Functional Display shows all relevant parameters: Current pressure dewpoint Operation mode Normal/Summer/Automatic Power consumption related to the whole life time Alarm signal Alarm history Maintenance necessary Operation status of the drain Operation hours Fridge compressor on/off Current energy consumption Oct. July Apr. Jan. 0 2 4 Time (24 hours) 00 90 0 70 0 40 20 0 0 Rel. energy consumption [%] This graphic shows a typical compressed air consumption of a one shift industrial plant. The full capacity is only required for a short time.
Technical Data Buran DC 0020 A - SD AP Type Airflow m 3 /h Airflow m 3 /min Pressure drop bar Power supply Power consumption kw 00% % V/ Hz Full load Part load 0% zero Cooling air m 3 /h Air connection BSP Weight kg Dimensions mm Width Height Depth Compact Classic DC 0020 A DC 00 A DC 00 A DC 005 A DC 005 A SD 000 AP SD 025 AP SD 0 AP SD 075 AP SD 0225 AP SD 00 AP SD 0375 AP SD 0 AP SD 0 AP SD 0 AP SD 07 AP SD 0 AP SD 000 AP SD 75 AP SD 0 AP SD 0 AP SD AP 20 5 5 00 25 75 225 0 375 7 000 75 0 0 0,33 0,5 0,3,0,42,7 2,0 2, 2,92 3,75 5,00,25 7, 9,7 0,3 2, 4,7,7 9,5 22, 25,00 27, 0,0 0,5 0,9 0,4 0,2 0,5 0,27 0,2 0,5 0, 0, 0,4 0,70 0,74 0,7 0, 0,95,0,25,2,45,0 2,40 2,5 2,0 2,95 3,0 0,3 0,4 0,2 0,9 0,40 0,4 0,39 0,4 0, 0,59 0,9 0,70 0,0 0,99,32,4,54,5,7 0, 0,2 0, 0,9 0,04 0,05 0,07 0,0 0,0 0,09 0,09 0, 0,3 0,3 0,5 0, 0,2 0, 0,3 740 740 000 000 0 2 2 2 2 0 2 2 2 2 " " " " 2 2 2 2 2 25 2 27 2 29 4 52 53 70 0 95 97 52 75 77 0 5 90 9 Compressed air inlet Compressed air outlet H Compressed air in and outlet H W D WB D Buran Compact DC 0020 A - DC 005 A Buran Classic SD 000 AP - SD AP Volume flow referred to the suction status of the air compressor (+ 20 C, bar), with compressed air inlet temperature C, operating overpressure 7 bar, ambient temperature 25 C, pressure dewpoint +3 C, measured at dryer outlet in accordance with DIN ISO 73. Permitted ambient temp.: min. + 2 C max. C, max. operating pressure: bar, higher pressure on request. Permitted inlet temp.: max. 70 C. Protection class IP 20, noise pressure level: db(a) <70. Working pressure bar g 2 3 4 5 7 9 0 2 3 4 5 f p 0,0 0,70 0,0 0, 0,94,00,04,0,09,0,2,4,5,,7 Dewpoint C 3 5 7 0 5 f tpd,00,2,24,3,45 Ambient temperature C ftu 25,00 0,97 0,94 40 0,7 45 0,75 0,2 Compressed air inlet temp. C fte,2,00 40 45 55 0 0, 0,75 0,5 0,4 0,3 5 70 0,42 0,40 Corrected dryer capacity = Standard dryer capacity x f p x f tpd x f tu x f te