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Wiped Film Molecular Distillation System
(Borosilicate Glass)
High distillation efficiency
Excellent separation performance
Precise control
Easy and safe operation
Overview
The main components of the glass short path molecular distillation are made of high borosilicate 3.3 material, and the evaporator is made of glass sintering, which is easy to clean without dead corners. At the same time, it reduces the number of interfaces and ensures high vacuum; the experimental materials are distilled from feeding to collecting materials. The process is intuitive and visual, and the parameter settings can be adjusted at any time according to the experimental phenomenon, which is convenient to quickly find the best process conditions. The high borosilicate glass also has good corrosion resistance, which is an ideal choice for experimental research and development or small-scale production.
Features
1. The glass parts are made of high borosilicate 3.3 material, with excellent visibility.
2. The magnetic coupling seal can maintain a higher vacuum degree to ensure the evaporation effect.
3. Scraper film forming design, contacting material part take stainless steel 316L+PTFE.
4. The sealing ring is made of fluorine rubber or tetrafluoroethylene, suitable for different material applications.
5. The main evaporator have been designed with full jacket and full insulation to ensure material fluidity.
6. Digital display pirani vacuum gauge, display high vacuum number.
7. Multi-plan structure configuration to guarantee different material and different process requirements.
8. Certification:UL、CE
3.3
High borosilicate glass
SS316L
SS316 wet parts & SS304 framework
≤300℃
The highest operating temperature
UL
UL sertified
0.1Pa
The lowest vacuum
PLC
Automatic digital control
Features
Biopharmaceuticals | Fine Chemicals | Food and Agriculture | Daily Chemicals | Fragrances and Flavors | Petrochemical Industry |
---|---|---|---|---|---|
(Deep-Sea and Fermented) Fish Oil | (Bisphenol A and F type) Epoxy Resin | Elaeagnus Mollis Oil | Polyethylene Glycol Ester | 3-Methylindole | B12042 |
Docosahexaenoic Acid (DHA) | Triethylene Glycol | Polyethylene Glycol Ester | L-Lactic Acid | Cedarwood Oil | Waste Oil Regeneration |
Eicosapentaenoic Acid (EPA) | 3-Hydroxypropionitrile (HPN) | Cholesterol-Removed (Beef Tallow and Lard) | Amino Acid Ester | Methyl Propionate | Glycerol Wastewater Recovery |
Polyether | Triethylene Glycol | Tocopherol (Natural and Synthetic) | Menthyl Ester | Angelica Extract | Saline Wastewater |
Methyl Salicylate | Alkylphenol | Sage Antioxidant | Lanolin Alcohol | Patchouli Oil (Patchoulol, Patchoulone) | Sulfonated Kerosene |
Glycolipid | Microcrystalline Wax | Alkyl Glycoside | Tea Tree Oil | Methyl Heptenone | Polyglycerol Ester |
Vitamin A | Polyolefin | Nicotine Purification | Lanolin | m-Toluic Acid | Polyether |
Vitamin E Acetate | Tributyl Phosphate | Glyoxylic Acid | Jasmine Essential Oil | Citral | Polyether Polyol |
Vitamin K Purification | Triethyl Phosphate | Organosilane Resin | Cane Wax | Cinnamaldehyde (Cinnamon Oil) | Mineral Oil Sludge Dewaxing |
Laurocapram | Neopentyl Glycol Dicaprylate | Sterol Ester | Litsea Cubeba Oil | Litsea Cubeba Oil | Asphalt Dewaxing |
Psoralea Corylifolia | Silicone Oil | Phytosterol | Peach Aldehyde | Methyl Salicylate | Coal Tar |
Ibuprofen Pivalate | Plasticizer | Perilla Seed Oil | Cetyl Alcohol | Sandalwood | Nano Pigment Removal of Toluene |
Tea Tree Oil | Polyhydric Alcohol | Palm Oil | Polydimethylsiloxane | Peach Aldehyde | Biodiesel (Fatty Acid Methyl Ester or Ethyl Ester) |
Bupleurum Volatile Oil | Dimer Acid | Monoglyceride (Monostearin, Monolaurin, etc.) | Vetiver Oil | Vetiver Oil | Graphite Acid Dehydration |
Agarwood | Silicone Oil (Polysiloxane or Polysilicone Ether) | Polysaccharide Ester | Polyglycerol Ester | Geraniol | Petroleum Residual Oil |
Garlic Oil | Aromatic Isocyanate | Lycopene | Polyether Silicone | Synthetic Jasmine Aldehyde | Hydrocarbon Compound |
Monoglyceride | Fluorinated Oil (Perfluorocarbon, Fluorochlorocarbon Oil, Perfluoropolyether) | Conjugated Linoleic Acid | Polyolefin | Long-Chain Dicarboxylic Acid (C9-C18) | Glutaraldehyde |
Polyunsaturated Fatty Acids | Glycerol | Silicone Oil (Dimethylpolysiloxane) | Polyethylene Glycol (Ester) | Ionone | Liquefied Coal |
Peptide | Curing Agent (Removing TDI, MDI, HDI, etc.) | Walnut Oil | Capsaicin | Vacuum Pump Oil | |
Entecavir Intermediate 7 | Silane Coupling Agent | Squalene | Rose Oil | Brake Fluid |
Cases
#A
TYPE
External single cold trap structure, liquid nitrogen or dry ice can be selected, high cost performance, and good cooling effect
#B
TYPE
External single-coil condenser structure, supporting low-temperature circulator, can meet the needs of different temperatures
#C
TYPE
External cooling coil condenser + cold trap can meet more material needs
#D
TYPE
The structure of the external double-coil condenser is convenient and flexible for temperature control to meet more temperature needs
Model | HMD-60 | HMD-80 | HMD-100 | HMD-150 | HMD-200 |
---|---|---|---|---|---|
Operation temperature(℃) | ≤300 | ≤300 | ≤300 | ≤300 | ≤300 |
Vaccum Level(mbar) | ≤0.001 | ≤0.001 | ≤0.001 | ≤0.001 | ≤0.001 |
Rotation speed(rpm) | 50-300 | 50-500 | 50-500 | 50-500 | 50-500 |
Residue receiving flask(L) | 0.5 | 1 | 2 | 5 | 5 |
Distillate receiving flask(L) | 0.5 | 1 | 2 | 5 | 5 |
Cooling area of internal condenser(㎡) | 0.15 | 0.2 | 0.3 | 0.53 | 0.73 |
Feeding flask volume(L) | 0.5 | 1 | 1 | 2 | 5 |
Feeding rate(L/h) | 0.05-2 | 0.05-3 | 0.1-5 | 0.2-10 | 0.5-15 |
Effective evaporation area(㎡) | 0.07 | 0.1 | 0.15 | 0.25 | 0.35 |