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Product Advantage
1. Compact Size: Research projects are often conducted in laboratory or research settings, so freeze dryers need to have a small and compact design to save space and facilitate placement.
2. Versatility: Research projects may involve various types of samples and processing requirements, so freeze dryers typically feature versatility to accommodate different freeze-drying applications.
3. High Precision Control: Research projects often require high-precision temperature and vacuum control to ensure experiment accuracy and repeatability.
4. Data Logging and Monitoring: Research projects may require data logging and monitoring of the freeze-drying process, so freeze dryers usually have data recording and monitoring capabilities for researchers to track experiment progress.
5. Customizability: Research project requirements can vary greatly, so freeze dryers often offer a degree of customizability to configure and adjust according to specific needs.
6. Energy Efficiency: Research projects often involve long-running processes, so freeze dryers are typically designed with energy-efficient features to reduce energy consumption and improve efficiency.
7. Ease of Maintenance: Research projects often require frequent maintenance and cleaning, so freeze dryers are typically designed with structures that are easy to maintain and clean.
Technical Parameters
Model | SY-20F Standard | SY-20F Stoppering | |
Freeze Drying Area | ㎡ | 0.3 | 0.2 |
Cold Trap Temperature | ℃ | <-75 (no-load) | <-75 (no-load) |
Vacuum Level | Pa | ≤1 (no-load) | ≤1 (no-load) |
Shelf Temperature Range | ℃ | -55-+70 (no-load) | -55-+70 (no-load) |
Maximum ice capacity | kg/24h | ≥6 | ≥6 |
Number of Shelf Layers | pcs | 3+1 | 2+1 |
Material Tray | mm | 400×270 | 400×270 |
Shelf Spacing | mm | 70 | 100 |
Overall Power | kW | 3 | 4 |
Weight | kg | 300 | 300 |
Dimensions | mm | 1033×781×1580 | 1033×781×1704 |
Loadable Materials | L | 3 | 2 |
Defrost Mode | - | Electric Defrost | Electric Defrost |
Safety Devices | - | Audible Alarm, Emergency Stop Switch, Overpressure Protection | |
Power Supply | - | Single-phase 3-wire, 220 volts | Single-phase 3-wire, 220 volts |
Product Uses
1. Biomedical Research: Used for freeze-drying proteins, antibodies, cells, and other biological samples for laboratory research.
2. Pharmaceutical Development: Employed to prepare drugs, vaccines, biologics, etc., to enhance their stability and shelf life.
3. Food Science: Utilized to study novel food products, improve food texture, and preserve foods, such as freeze-dried fruits, coffee, and dairy products.
4. Materials Science: Applied for preparing nanomaterials, thin films, coatings, and porous materials for use in electronics, energy, and nanotechnology.
5. Environmental Science: Used to analyze and test organic compounds and pollutants in soil and water samples, contributing to the study of environmental pollution and ecosystem restoration.
6. Geology: Employed to prepare rock and mineral samples for analysis and geological exploration.
7. Textile and Pulp Industry: Used to enhance the performance of fiber materials, like pulp, textiles, and insulation materials.
8. Chemical Engineering: Utilized for freeze-drying chemicals, dyes, catalysts, etc., to improve their stability and ease of handling.
9. Archaeology and Cultural Preservation: Used to preserve cultural heritage, ancient artifacts, and archaeological samples.
10. Space Science: Employed for preparing spacecraft components, celestial samples, and cosmic dust for space research and exploration.
11. Agricultural Science: Used to research and improve crops, seeds, and soils to enhance agricultural production and food supply.
12. Virology and Microbiology: Applied for freeze-drying viruses, bacteria, and fungi samples for research and medical diagnostics.
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FAQ
In scientific research, the most common issues when using freeze-drying machines include:
Lack of Operational Skills: Being unfamiliar with the operation and control of the freeze-drying machine can lead to sample failure or poor results.
Improper Sample Preparation: Incorrect sample preparation, such as failure to pre-cool or freeze samples, can lead to issues during the drying process.
Vacuum Pump Problems: Malfunctioning vacuum pumps or inadequate vacuum levels can affect the effectiveness of freeze-drying.
Inaccurate Temperature Control: Problems with the temperature control system can result in overheating or overcooling of samples, affecting the drying process.
Improper Equipment Maintenance: Irregular equipment maintenance can lead to decreased performance of the freeze-drying machine, impacting work efficiency.
Addressing these issues typically requires training and operational experience to ensure the correct use and maintenance of the freeze-drying machine for reliable research results.
Product Advantage
1. Compact Size: Research projects are often conducted in laboratory or research settings, so freeze dryers need to have a small and compact design to save space and facilitate placement.
2. Versatility: Research projects may involve various types of samples and processing requirements, so freeze dryers typically feature versatility to accommodate different freeze-drying applications.
3. High Precision Control: Research projects often require high-precision temperature and vacuum control to ensure experiment accuracy and repeatability.
4. Data Logging and Monitoring: Research projects may require data logging and monitoring of the freeze-drying process, so freeze dryers usually have data recording and monitoring capabilities for researchers to track experiment progress.
5. Customizability: Research project requirements can vary greatly, so freeze dryers often offer a degree of customizability to configure and adjust according to specific needs.
6. Energy Efficiency: Research projects often involve long-running processes, so freeze dryers are typically designed with energy-efficient features to reduce energy consumption and improve efficiency.
7. Ease of Maintenance: Research projects often require frequent maintenance and cleaning, so freeze dryers are typically designed with structures that are easy to maintain and clean.
Technical Parameters
Model | SY-20F Standard | SY-20F Stoppering | |
Freeze Drying Area | ㎡ | 0.3 | 0.2 |
Cold Trap Temperature | ℃ | <-75 (no-load) | <-75 (no-load) |
Vacuum Level | Pa | ≤1 (no-load) | ≤1 (no-load) |
Shelf Temperature Range | ℃ | -55-+70 (no-load) | -55-+70 (no-load) |
Maximum ice capacity | kg/24h | ≥6 | ≥6 |
Number of Shelf Layers | pcs | 3+1 | 2+1 |
Material Tray | mm | 400×270 | 400×270 |
Shelf Spacing | mm | 70 | 100 |
Overall Power | kW | 3 | 4 |
Weight | kg | 300 | 300 |
Dimensions | mm | 1033×781×1580 | 1033×781×1704 |
Loadable Materials | L | 3 | 2 |
Defrost Mode | - | Electric Defrost | Electric Defrost |
Safety Devices | - | Audible Alarm, Emergency Stop Switch, Overpressure Protection | |
Power Supply | - | Single-phase 3-wire, 220 volts | Single-phase 3-wire, 220 volts |
Product Uses
1. Biomedical Research: Used for freeze-drying proteins, antibodies, cells, and other biological samples for laboratory research.
2. Pharmaceutical Development: Employed to prepare drugs, vaccines, biologics, etc., to enhance their stability and shelf life.
3. Food Science: Utilized to study novel food products, improve food texture, and preserve foods, such as freeze-dried fruits, coffee, and dairy products.
4. Materials Science: Applied for preparing nanomaterials, thin films, coatings, and porous materials for use in electronics, energy, and nanotechnology.
5. Environmental Science: Used to analyze and test organic compounds and pollutants in soil and water samples, contributing to the study of environmental pollution and ecosystem restoration.
6. Geology: Employed to prepare rock and mineral samples for analysis and geological exploration.
7. Textile and Pulp Industry: Used to enhance the performance of fiber materials, like pulp, textiles, and insulation materials.
8. Chemical Engineering: Utilized for freeze-drying chemicals, dyes, catalysts, etc., to improve their stability and ease of handling.
9. Archaeology and Cultural Preservation: Used to preserve cultural heritage, ancient artifacts, and archaeological samples.
10. Space Science: Employed for preparing spacecraft components, celestial samples, and cosmic dust for space research and exploration.
11. Agricultural Science: Used to research and improve crops, seeds, and soils to enhance agricultural production and food supply.
12. Virology and Microbiology: Applied for freeze-drying viruses, bacteria, and fungi samples for research and medical diagnostics.
| | |
FAQ
In scientific research, the most common issues when using freeze-drying machines include:
Lack of Operational Skills: Being unfamiliar with the operation and control of the freeze-drying machine can lead to sample failure or poor results.
Improper Sample Preparation: Incorrect sample preparation, such as failure to pre-cool or freeze samples, can lead to issues during the drying process.
Vacuum Pump Problems: Malfunctioning vacuum pumps or inadequate vacuum levels can affect the effectiveness of freeze-drying.
Inaccurate Temperature Control: Problems with the temperature control system can result in overheating or overcooling of samples, affecting the drying process.
Improper Equipment Maintenance: Irregular equipment maintenance can lead to decreased performance of the freeze-drying machine, impacting work efficiency.
Addressing these issues typically requires training and operational experience to ensure the correct use and maintenance of the freeze-drying machine for reliable research results.
