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    Fabric air permeability tester

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    Fabric Air Permeability Tester
    Fabric air permeability tester

    Fabric air permeability tester

     

    Fabric Air Permeability Tester is a lab instrument used to measure how easily air passes through a fabric. It quantifies the air permeability, which is crucial for evaluating breathability, comfort, and functional performance in textiles.

    Purpose Fabric Air Permeability Tester:

    It determines the rate of airflow through a fabric sample under a set air pressure, typically reported in units like cm³/cm²/s or L/m²/s.

    Working Principle:

    The tester creates a pressure difference across the fabric sample and measures the volume of air flowing through it. Higher air permeability means the fabric is more breathable.

    Main Components of Fabric Air Permeability Tester:

    – Test Head / Clamp: Holds the fabric securely without leakage.

    – Pressure Regulator: Maintains a constant air pressure during testing.

    – Flow Meter or Digital Sensor: Measures the actual airflow rate through the fabric.

    – Display Unit: Shows readings of air permeability instantly.

     

    Applications of Fabric Air Permeability Tester:

    – Performance textiles (sportswear, PPE)

    – Technical fabrics (filters, tents, airbags)

    – Medical textiles (masks, gowns)

    – Nonwovens and industrial materials

     

    Benefits of Fabric Air Permeability Tester:

    1. Accurate Breathability Measurement – Precisely measures how breathable a fabric is, essential for comfort and performance.
    2. Supports Quality Control – Ensures consistent air permeability in fabric batches, critical for products like PPE, sportswear, and filters.

     

    1. Enhances Product Design – Helps in selecting or engineering fabrics with the right airflow properties for specific uses.
    2. Standard Compliance – Conforms to international testing standards (e.g., ASTM D737, ISO 9237), ensuring global credibility.
    3. Quick and Reliable Testing – Provides rapid results, increasing lab efficiency and production decision-making speed.

     

    1. Wide Material Compatibility – Suitable for woven, nonwoven, knitted fabrics, and even paper or coated materials.
    2. Improves Functional Performance – Helps optimize products for ventilation, moisture control, and thermal comfort.
    3. Reduces Product Failure – Identifies underperforming fabrics early, minimizing risks in high-performance applications.

    Features of Fabric Air Permeability Tester:

    1. Digital Display – Shows air permeability readings clearly in units like L/m²/s or cm³/cm²/s.
    2. Precise Test Head/Clamp – Provides an airtight seal to prevent air leakage and ensure accurate results.
    3. Adjustable Pressure Settings – Allows testing under various pressure drops (e.g., 10–2500 Pa), depending on fabric type.

     

    1. Automatic Airflow Measurement – Built-in sensors or flow meters capture airflow rate automatically for quick analysis.
    2. Multiple Test Area Sizes – Interchangeable test plates to match different sample sizes and standard requirements.
    3. Data Logging and Export – Some models include USB or software connectivity for storing and exporting test results.

     

    1. Standard Compliance – Conforms to ASTM D737, ISO 9237, BS 5636, DIN 53887, etc.
    2. Robust Construction – Built with corrosion-resistant materials and durable components for long-term lab use.
    3. Low Maintenance – Simple cleaning and calibration process for reliable performance.
    4. Compact and User-Friendly Design – Ideal for lab benches and easy operation with minimal training.

    How to Use Fabric Air Permeability Tester:

    1. Prepare the Sample – Cut the fabric sample to the required size (usually circular, e.g., 20 cm²).
    2. Mount the Sample – Place the fabric securely in the test clamp or holder, ensuring no wrinkles or gaps.
    3. Set Test Parameters – Adjust the air pressure drop according to the fabric type or standard (e.g., 100 Pa).

     

    1. Start the Test – Turn on the air supply and start the airflow through the fabric.
    2. Read the Measurement – The digital display will show the air permeability value in the selected units.
    3. Record the Results – Note the readings or export data if the device supports it.
    4. Repeat if needed – Test multiple samples or areas for accuracy and average the results.
    5. Clean and Maintain – After testing, clean the clamp and ensure the device is calibrated regularly.

     

    Tip: Ensure the test environment maintains standard temperature and humidity for consistent results.

     

    Fabric Air Permeability Tester

    Appliance Range
    It is used to TEST the air permeability of various textile fabrics, including industrial fabrics, nonwoven fabrics and other textile products and other breathable materials.
    Related Standards
    GB / T 5453, GB / T 13764, ISO 9237, ISO 5636, ASTM D737, etc.

    Instrument characteristics
    1. Automatic sample clamping, automatic nozzle replacement, and quick test.
    2. Microcomputer processing, the test results are displayed directly, without manual table calculation;
    3. Built-in continuous test mode, the test unit can be switched as needed.
    4. Chinese LCD menu operation, configure computer interface.

    Technical parameter
    1. Range of sample pressure difference: 1 ~ 4000Pa
    2. Measurable air permeability: 1 ~ 40,000mm / s
    3. Measurement error: ≤ ± 2%
    4. Measurable fabric thickness: ≤8mm
    5. Test area: 5cm2; 20cm2; 50cm2; 100cm2
    Ф50mm (≈19.6cm2)
    Ф70mm (≈38.5cm2)

    6. Nozzles: 11 in total (automatic replacement of digital setting)
    CODE 00 01 02 03 04 05 06 07 08 09 10
    DIAφ(mm)
    0.8 1.2 2 3 4 6 8 10 12 16 20
    7.Data Capacity:≤200 times tests
    8.Power Supply:AC220V 50Hz 2KW
    9.Weight:80Kg
    10.Shape:1250×700×1250mm

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      2. Solvent Evaporation Plate- Heats and evaporates solvent quickly, leaving only the oil residue.
      3. Digital Display - Shows time, temperature, and process status for user-friendly operation.
      4. Compact and Durable Design - Made with corrosion-resistant materials suited for chemical handling.
       
      1. Safety Features - Includes overheat protection and enclosed solvent chamber to reduce exposure risk.
      2. Standard Compliant - Designed to meet GB/T 6504-2017 and similar industry testing standards.
        How to Use Fiber Oil Fast Extractor:
      1. Prepare the Sample - Cut 5–10 g of fiber or yarn into small pieces and place in the sample tube.
      2. Add Solvent - Pour a suitable solvent (e.g., petroleum ether) into the tube to cover the sample.
      3. Apply Weight - Place the extractor's weight or press system onto the sample to aid extraction.
       
      1. Start Extraction - Activate the machine. The solvent dissolves the oils and flows to the heating plate.
      2. Heat for Evaporation - Set the temperature (typically 90–120°C). The solvent evaporates, leaving oil on the plate.
      3. Measure Oil Content- After drying, weigh the remaining oil. Use the built-in calculator or formula:
      Oil % = (Oil weight / Original sample weight) × 100
      1. Clean the Unit - After cooling, clean all parts to prepare for the next test.
        Fiber Oil Fast Extractor

        Fiber Oil Fast Extractor

       
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      Laboratory Padder
      Laboratory Padder

      Laboratory Padder

      $0.00

      Laboratory Padder

      Laboratory Padder

      Mini Lab Dyeing Padder

      A Laboratory Padder is a compact, laboratory-scale machine used to apply liquids like dyes, chemicals, and finishes to fabric samples. It simulates the padding process in textile manufacturing, where fabric is passed through a liquid solution, then squeezed between rollers to ensure uniform application and absorption.   Key Features of a Laboratory Padder:
      1. Adjustable Rollers - The fabric is passed through two or more rollers to apply even pressure and squeeze out excess solution, ensuring uniform chemical or dye application.
      2. Variable Pressure Control - Allows adjustment of roller pressure for different fabric types and chemical formulations, ensuring optimal penetration without damage.
       
      1. Solution Bath - Holds the liquid (e.g., dye, finish, or other chemical treatments) in a bath through which the fabric is dipped before passing through the rollers.
      2. Fabric Speed Control - Adjustable conveyor speed allows for control over the time the fabric spends in contact with the liquid solution, affecting the degree of treatment.
       
      1. Digital Control Panel - Provides easy adjustment of pressure, speed, and solution volume to ensure precise and reproducible results.
      2. Compact Design - Smaller, lab-scale version of industrial padders, ideal for research, development, and small-scale testing.
       
      1. Safety Features - Safety guards, emergency stops, and proper handling mechanisms to prevent accidents during operation.
      Applications: - Dyeing: For even application of dye or pigment on fabric. - Finishing: Applying finishes like softeners, water repellents, or flame retardants. - Chemical Treatments: Applying various chemicals used in textile manufacturing, such as anti-microbial treatments or stain-resistant solutions. - Shrinkage Testing: Simulating treatments to test fabric behavior under different conditions.   Benefits of Laboratory Padder:
      1. Precise Application of Chemicals - Provides uniform and controlled application of dyes, finishes, and other chemicals, ensuring consistent results.
      2. Small-Scale Testing - Ideal for small sample testing, allowing for fabric treatment without needing full-scale production equipment.
       
      1. Versatile Use - Suitable for dyeing, finishing, and applying various chemical treatments, making it a flexible tool for R&D labs.
      2. Cost-Effective - Reduces the need for large-scale machinery and the associated costs, while providing reliable results for small batches.
       
      1. Controlled Fabric Treatment - Offers adjustable pressure, speed, and solution concentration, enabling fine-tuned processing for different fabric types and applications.
      2. Accelerates Development - Speeds up the testing and development of new products or finishes, improving time-to-market for textile manufacturers.
      3. Energy Efficient - Consumes less energy compared to larger, industrial-scale machines, making it suitable for lab use.
      4. Compact and Space-Saving - Designed for laboratory environments with limited space, without compromising on functionality.
       
      1. Reproducible Results - Ensures consistent application of treatments across multiple samples, aiding in accurate testing and comparison.
        Features of Laboratory Padder:
      1. Adjustable Roller Pressure - Allows precise control over the pressure applied to the fabric, ensuring uniform chemical or dye application.
      2. Variable Speed Control - Adjustable conveyor speed for controlling the time the fabric spends in the solution bath, influencing the absorption rate.
       
      1. Solution Bath - Holds dye, chemicals, or finishes, and the fabric passes through this bath before moving to the rollers.
      2. Digital Control Panel - Easy-to-use interface for setting and adjusting parameters like speed, pressure, and solution concentration.
       
      1. Compact and Lab-Friendly Design - Designed for smaller, space-efficient use in textile labs, allowing for small sample testing.
      2. Roller Gap Adjustment - Allows for fine-tuning of the gap between rollers to regulate the amount of solution squeezed out of the fabric.
       
      1. Stainless Steel Construction - Durable and resistant to corrosion from the chemicals used in textile treatments.
      2. Safety Mechanisms - Includes safety guards, emergency stops, and user protection features during operation.
      3. Even and Controlled Application - Ensures even distribution of treatments (dye, finish, etc.) on fabric with minimal waste.
      4. Versatility in Application - Can be used for a wide range of textiles and treatments, including dyeing, softening, flame-retardant treatments, etc.
        How to Use a Laboratory Padder:
      1. Prepare the Fabric Sample - Cut the fabric sample to the required size for the experiment. Ensure it’s clean and free of any debris.
      2. Prepare the Solution - Mix the dye, chemical, or finish solution according to the desired concentration and the fabric's needs. Ensure that the solution is homogeneous.
       
      1. Set the Parameters - Pressure: Adjust the roller pressure based on the fabric type. Different fabrics require different pressure levels to ensure uniform application. - Speed: Set the fabric conveyor speed depending on the desired treatment time (longer exposure for deeper treatment).
      - Roller Gap: Adjust the roller gap to control the amount of liquid squeezed out from the fabric.  
      1. Load the Fabric into the Machine - Place the fabric carefully into the machine. The fabric should go through the solution bath and then pass between the rollers.
      2. Start the Machine - Turn on the machine and allow the fabric to pass through the rollers. The solution will be evenly applied to the fabric as it moves through the bath and is squeezed by the rollers.
       
      1. Monitor the Process - Keep an eye on the fabric to ensure it is being treated uniformly and there are no blockages or fabric jams.
      2. Unload the Fabric - Once the fabric has been treated, carefully remove it from the machine. Inspect for even application of the solution and any excess liquid.
       
      1. Dry or Process Further - Depending on the treatment, proceed with further steps such as drying, heat setting, or curing, as required by the experiment or process.
      Safety Tips:- Always wear appropriate personal protective equipment (PPE), such as gloves and goggles, when handling dyes or chemicals. - Ensure the machine is turned off and the rollers are stopped before attempting to remove or adjust the fabric.   Laboratory Padder dealer In Bangladesh, Lab Padder Importer in Bangladesh, Laboratory Padding mangle in Bangladesh, Laboratory Padding mangle in Bd, Laboratory Padder  Price in Bangladesh, Laboratory Padder in Bangladesh, Laboratory Padding mangle price in Bangladesh       Laboratory Padder
      Laboratory Padder

      Mini Lab Dyeing Padder

      Brand: DUNLIN Model:PM-A1 Origin: China Roller position: Vertical Rollers width :450mm Rollers diameter:125mm Rubbers hardness: 70degree shore Cloth speed: 0-10m/min Standard pressure: 0.6Mpa Retained dyestuff ratio: 40-80% Power supply: 1∮AC 220V 50/60HZ Dimensions (L x W x H):710 x 600x 1340mm Standard Accessories English manual Certificate of quality. Laboratory Padder Machine Dunlin price in Bangladesh Laboratory Padder Machine Dunlin in textile Textile testing equipment in Bangladesh Textile testing equipment in Dhaka Textile testing equipment in Uttara MAAM tex Laboratory Padder Machine Dunlin price in BangladeshLaboratory Padder
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      Digital hot plate-magnetic stirrer
      Color Matching Cabinet -light Box

      Digital hot plate-magnetic stirrer

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      Digital hot plate-magnetic stirrer

      Digital hot plate-magnetic stirrer

      Digital hot plate-magnetic stirrer

        A digital hot plate-magnetic stirrer is a laboratory device that combines two essential functions: heating and stirring. It is widely used in chemistry, biology, and physics laboratories for preparing solutions, mixing chemicals, and conducting experiments that require controlled heating and stirring. Model : (DL-300) Brand : DUNLIN Origin : TAIWAN Set-up plate Dimensions : Ø 135 mm Motor type : DC Motor Speed range : 0-1500 rpm Display : 5 Inch LED Display Heating temperature range : Room Temp. 0-280°C Temperature display : 5 Inch LED Display Temperature display accuracy : ±0.1 Protection class according to DIN EN 60529 : IP42 Power Supply : 200-240V 3A Dimensions ( W x D x H ) : ( 255 x 152 x 80 ) mm Key Components of Digital hot plate-magnetic stirrer: Hot Plate (Heating Element): - Provides a flat surface that heats up electrically. - Controlled via a digital interface for setting precise temperatures. - Often features over-temperature protection for safety.
      1. Magnetic Stirrer:
      - Uses a rotating magnetic field to spin a magnetic stir bar placed in the liquid. - Ensures even mixing of the solution without manual stirring. - Speed can be adjusted digitally.  
      1. Digital Display and Controls:
      - Allows precise setting of temperature and stirring speed. - Typically includes an LCD or LED screen. - Some models have programmable settings and timers.  
      1. Temperature Sensors:   - Built-in or external probes (like a PT100 or thermocouple) for accurate temperature control.
        Features of Digital hot plate-magnetic stirrer: - Temperature Range: Usually ranges from ambient to 300°C or higher. - Stirring Speed: Typically ranges from 100 to 1500 RPM. Material: The top plate is often made from ceramic, aluminum, or stainless steel to ensure durability and chemical resistance.   Applications Digital hot plate-magnetic stirrer: - Dissolving solids in liquids. - Heating samples while stirring to ensure uniform temperature distribution. - Conducting chemical reactions that need constant stirring and controlled heat. - Biological and pharmaceutical sample preparation.     Benefits of using a Digital Hot Plate & Magnetic Stirrer in laboratory and industrial settings:
      1. Precision and Control- Digital Interface: Allows accurate setting and monitoring of temperature and stirring speed.- Consistent Results: Ensures reproducibility in experiments and solution preparations.
       
      1. Efficient Mixing and Heating- Uniform Mixing: Magnetic stirring eliminates hotspots and ensures even distribution of solutes.- Simultaneous Operation: Ability to heat and stir at the same time improves efficiency.
       
      1. Safety Features- Overheat Protection: Prevents accidents by automatically shutting off at unsafe temperatures.- Sealed Surface: Reduces risk of contamination and easy to clean.
       
      1. Versatility
      - Suitable for a wide range of applications including chemical synthesis, biological experiments, and pharmaceutical processes.- Compatible with various types of containers and volumes.  
      1. Compact and User-Friendly- Takes up minimal bench space.- Simple to operate with user-friendly controls and displays.
      2. Durability- High-quality materials like ceramic or stainless steel tops resist corrosion and wear.
      3. Time-Saving Speeds up preparation of solutions and reactions compared to manual stirring and separate heating. Would you like these benefits presented in a slide format or for a product brochure?
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