industrial continuous vacuum dryer hollow blade dryer vacuum paddle dryer
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DESCRIPTION
Dual counter-rotating shafts with unique intermeshing hollow wedge-shaped paddles produce intimate mixing, optimize heat transfer,and provide a self-cleaning feature. A large heat transfer area to volume ratio is achieved by the use of hollow paddles and ajacketed vessel, through which the heating medium flows. The result is an efficient, compact machine with less space requirements and lower installation cost.
WORKING PRINCIPLE
The Hollow Paddle Dryer has a metal wall which separates the process mass from the heat source (steam or hot oil). High thermal efficiency is obtained because the heat from the thermal medium goes directly into the process mass. As the material comes into contact with the heated through and agitators, the process mass is heated via conduction. With an insulated dryer, very little heat is lost. To evaporate 1kg of water only requires about 1.2kg of steam for slurry materials. Exhaust gas is minimal and at a low temperature. Therefore, the volume of non-condensable gas from the dryer, which might require treatment, is minimal.
The dryer is an indirect heat transfer device which utilizes a high degree of mechanical agitation to enhance contact with the product being dried. Evaporation rates per square foot of heat transfer surface are maximized through self-cleaning paddles and the mixing effect. Movement of the process material between the slanting surfaces of the revolving wedge-shaped paddles generates shearing forces, which clean the paddle surfaces and maximize conductivity. Counter rotating shafts move the material away from the walls, cleaning the walls by means of the tab on each paddle. This results in higher heat transfer rates than disc or single shaft designs.
The wedge-shaped paddles, and the intermeshing of the dual agitators, create a localized mixing effect around the paddle. This allows more individual particles in the bed to be exposed directly to the heat transfer surface, thereby increasing the heat transfer rate, allowing the use of smaller equipment.
Project model | KJG3 | KJG9 | KJG13 | JYG18 | KJG29 | KJG41 | KJG52 | KJG68 |
Heat transfer area (M2) | 3 | 9 | 13 | 18 | 29 | 41 | 52 | 68 |
Effective volume (M3) | 0.06 | 0.32 | 0.59 | 1.09 | 1.85 | 2.8 | 3.96 | 5.21 |
Speed range (RMP) | 15-30 | 10-25 | 10-25 | 10-20 | 10-20 | 10-20 | 10-20 | 10-20 |
Power (kw) | 2.2 | 4 | 5.5 | 7.5 | 11 | 15 | 30 | 45 |
Body width a (mm) | 306 | 584 | 762 | 940 | 1118 | 1296 | 1476 | 1652 |
Total width b (mm) | 736 | 841 | 1066 | 1320 | 1474 | 1676 | 1854 | 2134 |
Body width C (mm) | 1956 | 2820 | 3048 | 3328 | 4114 | 4724 | 5258 | 5842 |
Total length d (mm) | 2972 | 4876 | 5486 | 5918 | 6808 | 7570 | 8306 | 9296 |
Feeding and discharging distance E (mm) | 1752 | 2540 | 2768 | 3048 | 3810 | 4420 | 4954 | 5384 |
Center height f (mm) | 380 | 380 | 534 | 610 | 762 | 915 | 1066 | 1220 |
Total height h (mm) | 762 | 838 | 1092 | 1270 | 1524 | 1778 | 2032 | 2362 |
Steam inlet n (inch) | 3/4 | 3/4 | 1 | 1 | 1 | 1 | 11/2 | 11/2 |
Outlet o (inch) | 3/4 | 3/4 | 1 | 1 | 1 | 1 | 11/2 | 11/2 |