HUMIDIFICATION BOTTLE filters moisture bottle oxygen bottle filter
humidification bottle filters Parameter
| Parameter Category | Specific Indicator | Description |
| Material | Ultra-high molecular weight polyethylene (PE) | Medical-grade raw material, non-toxic, resistant to strong acids and alkalis, high chemical stability |
| Filter Precision | 0.2μm–150μm (customizable) | Uniformly distributed micro-pores, small bubble diameter (standard type: 0.2–1μm) |
| Operating Temperature | -30°C to 100°C | High-temperature sterilization resistant, suitable for various disinfection environments |
| Pressure Range | 0.1–0.6 MPa | Pressure resistance ≥4 MPa, suitable for high-pressure oxygen flow |
| Dimensions | Standard: 10×7×39 mm (customizable) | Customizable tubular, disc-shaped, or irregular components based on humidifier bottle structure |
| Special Properties | Hydrophobic, DNase/RNase-free | Prevents liquid backflow, free from nucleic acid enzyme contamination |
Note: Some filter cores use a dual-layer structure (e.g., macroporous layer + microporous layer), further refining bubbles (microporous layer pore size 0.2–1 μm), improving noise reduction by 30%.
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humidification bottle filters Production Process
Humidifier bottle filter core production combines sintering technology with quality control, completed in five steps:
Raw material pretreatment:
Screen ultra-high molecular weight PE particles, clean to remove impurities, and dry.
Forming process:
Sintering forming: PE particles are filled into a mold and sintered under high temperature (200–300°C) and pressure to form a microporous structure.
Wet forming (optional): PE fibers are mixed with a binder (such as PVA) to form a slurry, which is then molded or coated, followed by drying and curing.
Post-processing:
Surface modification: Immersed in acid/alkali solutions to enhance surface functional group adsorption.
Activation treatment: Mild activation at 600–900°C in an inert gas environment to restore porosity.
Quality inspection:
Seal integrity test (0.5 MPa pressure), filtration efficiency verification (98% or higher retention of 0.5 μm particles), and pressure resistance test.
Cleaning and Packaging:
Rinsing with deionized water until conductivity <10 μS/cm, drying at 60–100°C, and dust-proof packaging.
humidification bottle filters Advantages
Performance Advantages:
High-efficiency humidification: Microporous structure generates fine bubbles, increasing contact area by 50%, with humidification efficiency superior to traditional aeration tubes.
Significant Noise Reduction: Bubble rupture noise reduced by over 10 dB, improving the ward environment.
Safety Advantages:
Zero Contamination Risk: Medical-grade PE contains no CNase/DNase and is SGS-certified (e.g., CANEC1818655002).
Cross-Contamination Prevention: A hydrophobic layer blocks humidification fluid backflow, preventing oxygen pipeline contamination.
Design Advantages:
Flexible customization: Supports non-standard sizes (e.g., irregular shapes, multi-layer structures) and functional adjustments (e.g., adding activated carbon).
Cost-effectiveness:
Lifespan of 6–12 months (under normal use), with low maintenance costs.
humidification bottle filters Application
| Field | Application Scenario | Function |
| Medical oxygen supply | Hospital central oxygen supply systems, home oxygen commentators | Humidify and dry oxygen to protect respiratory mucous membranes |
| Emergency and Intensive Care | ICU, Emergency Department, Respiratory | Department Used with disposable humidification bottles to prevent cross-infection |
| Portable Medical Devices | Oxygen bags, portable ventilators | Integrated with small filter cores (e.g., 5mm diameter) for lightweight design |
| Industrial Gas Processing | Gas filtration, laboratory gas line purification | Corrosion-resistant for chemical waste gas treatment |
Humidifier bottle filters combine materials science and precision manufacturing to address the three major pain points in medical oxygen therapy: humidification efficiency, noise, and infection control. Future trends include the application of nanomaterials (e.g., TiO₂ loading for enhanced sterilization) and intelligent production (real-time monitoring of process parameters), further expanding into high-end medical and environmental protection fields.