Chiuvention Instruments
SmartPull
The SmartPull Fabric Tensile Tester is AC servo-driven. It has ball screws to provide a stable pulling force. This setup leads to higher testing accuracy. The fabric tensile tester machine’s software is compatible and powerful. It outputs many test indexes, such as displacement, greatest force, elongation, and stress. It also has many safety features to protect the instrument and the operator. It is a universal tensile machine. ChiuVention Engineers created the tensile tester for textiles, leather, and footwear.
It can perform tension, compression, bending, tearing, shearing, peeling, and top-breaking tests. It applies to many international standards. These include ISO 9073-3, ISO13934-1/2, ASTM D5034, ASTM D5035, ISO 3377-2, ISO 13937-3, FZ/T 01030, GB/T 19976, and more.
SmartPull tensile tester machine applies to many standards and optional standards such as ISO 3377-2, ISO 13934-1/2, ISO 13937-2/3, ISO 20932-1, ASTM D5034, ASTM D5035, ASTM D5587, GB/T3917.2, FZ/T 01030, ISO 9073-4, ISO13934-1/2, ISO 9073-3, ISO 13937-2/3, ISO 4674-1, GB/T 3917.4, GB/T 3923.1, ISO 2062, ASTM D6797, GB/T 19976.
SmartPull Fabric Tensile Tester
Test capacity: 250kg ( 500kg is optional and the appearance will change)
Test level: class 1
Max travel: 800 mm (without fixture)
Travel accuracy: ≤1%
Traverse speed: 1mm/min ~ 500mm/min
Speed accuracy: ≤1%
Test force range: 0.2%~100% FS
Force accuracy: ≤1%
Power: 220 /110V 50Hz/60Hz
Weight: 90kg
Dimension: 630*460*1470 mm (D*W*H)
Software configuration (standard): version A of the test system, with a single-step test
Software configuration (optional): version C of the testing system can achieve multi-step test
Fixture and standards
Version A :
ISO 9073-3, ISO 13934-1, ISO 13934-2,
ASTM D5034, ASTM D5035,
GB/T 3923.1, GB/T 3923.2, GB/T 13773.1, GB/T 13773.2, GB/T 24218.3
(The standards above are matched with clamps by 25×25 mm, 25×50 mm, 25×75 mm)
Optional Fixture and standards
Clamps by 25×100 mm: ISO 9073-4 GB/T 3917.3
Clamps by 50×75 mm : ASTM D5587
Leather tearing fixture: ISO 3377-2
Top breaking fixture: ASTM D6797 FZ/T 01030 GB/T 19976
Yarn fixture: ISO 2062
Version A+: ISO 13937-2 (Sample 50 mm wide)ISO 13937-3
GB/T 3917.2 (Sample 50 mm wide) GB/T 3917.5
Clams by 25×200 mm: ISO 13937-4 ISO 4674-1 GB/T 3917.4
Version C: ISO 13936-2, ASTM D4964 (U type fixture)
VersionC+: ASTM D434 ASTM D1683 ISO 13936-1
ISO 20932-1( with linear clamps, or choose other fixtures and replace the clamps)
(The standards above should be programmed according to the test requirements provided by customers.)
Accessory of SmartPull Tensile Strength Tester Machine
Standard accessories: pins, operation manuals, power cords, communication cords, control panels, fuses
Optional accessories: sampling plate
Computer Configuration of SmartPull Tensile Strength Testing Equipment (Optional)
CPU for the Intel Celeron (Celeron) 2GHz or more CPU
Memory at least 512MB, more than 1GB is better
Hard disk space of more than 2GB
Display resolution of 1024 × 768 or more.
If you need output reports, you should use a printer that is compatible with the operating system.
The operating system should be Microsoft’s Windows XP, Windows 7, Windows 8, Windows 10
A fabric textile tensile tester is a machine. It measures the strength and stretchiness of fabrics. It works by gripping a strip of cloth or other materials, such as leather, paper, or yarn, on both ends. Then, you pull it until it breaks. Advanced sensors measure the force needed to remove the fabric. They also measure how far it stretches before breaking. This gives quantitative data on the fabric’s tensile properties.
The most common testing machine used for tensile testing is the universal testing machine(UTM). It features two crossheads: one is adjusted to accommodate the length of the specimen, while the other is driven to apply tension to the test specimen. These testing machines can be either electromechanical or hydraulic.
For accurate testing, the machine must have appropriate capabilities for the test specimen, including sufficient force capacity, speed, precision, and accuracy. Various accessories, such as grips, extensometers, and temperature chambers, are used to adapt the machine for different materials and testing conditions.
The SmartPull Fabric Textile Tensile Tester software is easy to use. It presents detailed tensile test results. These include elongation, time, greatest force, and modulus. They also include breaking force and more. It allows you to compare past results. You can also export data and create custom tensile strength test reports.
Preparation
Check the equipment: Before starting the calibration, make sure that there is no physical damage to the Tensile Strength Tester itself, and that the sensors, fixtures, display, and other parts are working properly.
Ensure leveling: The Tensile Strength Tester must be placed on a level workbench to avoid tilting the machine resulting in inaccurate testing. Use a level or the leveling function that comes with the machine to check.
Calibrate the load cell (force transducer)
Selection of standard weights: Select standard weights of known accurate quality. It is usually necessary to use calibration weights that comply with national or international standards. The range of the weights should cover the operating range of the Tensile Strength Tester.
Hanging weights: Hang the weights on the transducer according to the operating manual of the Tensile Strength Tester. Make sure the weights are hung at the correct position and angle to prevent deviations in the test force values.
Record display readings: After loading the weights, observe and record the force values displayed by the Tensile Strength Tester and compare them with the actual force values of the weights.
Adjust the calibration coefficient: If the force value displayed by the Tensile Strength Tester does not match the actual force value of the standard weights, use the calibration function that comes with the machine or adjust the calibration coefficient through the software until the displayed force value is consistent with the weights.
Displacement sensor calibration
Check the zero point of the displacement sensor: without loading any force, check whether the displacement displayed by the Tensile Strength Tester is zero. If there is deviation, reset the zero point of the displacement transducer.
Measure standard displacement: Using a standard calibration fixture, set the tensioner to move a certain distance (e.g., 10 mm, 50 mm, etc.) and then record the displacement reading displayed by the tensioner.
Adjusting Displacement Calibration: Compare the actual displacement with the displacement displayed by the Tensile Strength Tester. If there is a deviation, adjust accordingly according to the equipment manual.
Speed calibration
Set Speed: Set the tensioner to a known travel speed (e.g. 10 mm/min) and start the tensioner.
Use a stopwatch or other measuring tool: Use a stopwatch to measure the actual distance and time traveled by the fixture or fixture beam and calculate the actual speed.
Adjust the speed parameters: If the actual speed does not match the set speed, make adjustments according to the calibration method of the device to ensure the accuracy of the speed setting.
Verify the calibration
After completing the calibration of the load cell, displacement sensor, and speed, perform the following verification steps:
Repeat the calibration process: Load the weights and measure the displacement and velocity again to verify that the calibration is accurate and stable.
Compare reference equipment: If possible, compare tensile test results with other calibrated reference Tensile Strength Testers to ensure consistency.
Adjustment of environmental conditions
When calibrating, make sure that the environmental conditions are consistent with actual use, including temperature and humidity. These conditions can affect the tensile test results, so ensuring the stability of the environment in which the Tensile Strength Tester is located is a critical part of calibration.
The SmartPull Fabric Textile Tensile Tester weighs 90 kilograms. This is due to its optimized design. So, it’s easier to move and use. This tensile machine uses the latest technology. This includes AC servo motors and precision ball screws. They make force accuracy better. Its improved hardware and software make the testing 20% more reliable.
It has an emergency stop button and an overload protection system. It also has travel range limits and warns about abnormal torque or issues. Its ergonomic design reduces injury risks.
Before using our tensile testing equipment, check the installation guide for environmental needs and machine securing. Connect electricals according to source rating specifications. Initialise when empty and tare the tester. Next, calibrate in ascending and descending order. Use deadweights certified for 20% to 100% of the capacity range. Save calibration results for further use.
Select matching international test standards based on fabric type. Set suitable grips, jaws, or fixtures. Input the recommended test speed, pre-tension rate, and gauge length as per standard. Specify the allowed elongation percentage without damage. Check if the data recording rate meets the standard. Zero the balance force sensor. Verify the alignment and centering of loaded fabric samples. Start the auto-return on the sample break.
Use pneumatic grips with rubber coating to hold dense, woven fabrics. Use smooth, lightweight mechanical clamps for light, sheer fabrics to avoid damage. Inspect across the width to check the center while loading. Observe the tensioning display to check for slackness or issues. Start a pre-tension cycle to correct minor orientation deviations.
If you see variability, recheck the grip pressure settings. Also, replace worn-out jaws. Recalibrate the load cell if accuracy declines beyond the permissible limit. Confirm that you have pre-conditioned the specimen. Verify that mounted gauge length dimensions are accurate. Increase the sample size or test repeats for more statistical confidence. Compare against certified reference equipment. The room temperature and humidity were stable throughout the entire test duration.
People replace consumable parts. These parts include grips, jaws, load cell mounts, couplings, pulleys, and drive belts. They wear out over time. Calibrated spare sensors and load cells can cut potential downtime. Other recommended spares are fuses, cords, and pneumatic component kits. Their typical replacement frequency varies. The frequency of use determines their usage.