Cell Instruments Co., Ltd.

Background Plastic films and sheets are typically made by melting polymer material and then shaping it through processes like extrusion or calendaring. During this production, the material is stretched in the machine direction, and as it cools, some internal stresses remain. When reheated, these stresses can cause the material to shrink, altering its dimensions. This shrinkage is crucial for quality and process control in plastic manufacturing. It helps assess process consistency, adjust production parameters, and understand material characteristics. Industries like packaging rely on shrinkage data to ensure precise fit after heat exposure. In essence, shrinkage is a key factor in maintaining product quality and process efficiency in plastic film and sheet production. Application The FST-01 Film Free Shrink Tester is used to measure the unrestrained linear thermal shrinkage of plastic film and sheets at specified temperatures in a fluid medium. This device helps assess how much these materials will shrink when exposed to heat in real-world applications. Test Process 1. Temperature Setup and Stabilization: Set the temperature on PID controller and the fluid is heated to a preset temperature and temperature is stabilized. 2. Specimen Preparation and Submersion: Mount the test specimen into the free shrink holder. Submerge them together into the liquid bath. 3. Time Monitoring and Completion: The timer starts to count down and when the test time is reached, an alarm will beep, signaling the end of the test. 4. Test Conclusion: Carefully remove the test specimen from the liquid bath. Press the Stop button on the tester to mark the conclusion of the test. 5. Shrinkage Measurement and Assessment: Treat test specimen in ambient environment and Measure the linear shrinkage of the specimen. Calculation To calculate the unrestrained linear shrinkage percentage using the given formula: Unrestrained Linear Shrinkage (%) = [(Lo - Lf) / Lo] x 100 Where: Lo = Initial length (100 mm) Lf = Length of the side after shrinking Technical Features 1. Precise P.I.D. temperature control 2. High-precision timer 3. Alarm capability 4. Consistent fluid medium heating 5. Inclusion of a standard square metal clamp and a free shrink holder 6. Equipped with an oil bath cover Standard: ASTM D2732 Main Parameters Sample Size â?¤160 mm x 160 mm Temperature Range Ambient ~ 200C Accuracy ±0.3 C Dimension 37*44*28 LWH cm Power Supply 220V 50Hz

Application The FSR-01 Shrink Force and Ratio Tester serves the purpose of measuring both the shrinking forces and shrinkage ratio of heat shrinkable films. These films are typically created through extrusion and stretching (hot drawing) during their manufacturing process, retaining this stretched state even after cooling. When the heat shrinkable film is reheated to the temperature at which the initial stress was introduced and subsequently fixed during its production, this stress is released, causing the film to contract or "shrink back." Depending on the specific manufacturing treatment applied, the film can be categorized as either biaxially oriented (stretched in two directions) or uniaxially oriented (stretched in one direction). Test Process 1. A well-insulated air oven is heated to the set temperature. The two samples are placed separately on two test stations, for shrinkage rate and shrink/contraction force testing. 2. A temperature probe is located to measuring area, to give result as reference temp. The air oven is driven down automatically to cover the sample area. The force and shrink rate are to be measured and the shrinkage temperature is reached when the maximum shrinking force is attained. 3. When this force has decreased by around 15%~30%, the air oven is lifted and time is recorded. 4. The assessment of shrinkage ratio is performed at the mean time. Technical Features 1. PLC Control and HMI Touch Screen: ensuring industrial-level stability. 2. Well-Insulated Air Oven: The air oven is excellently insulated and capable of automatic lowering and lifting, enhancing the precision of the testing. 3. Non-Contact Shrink Ratio Measurement: accomplished through a noncontact method, improving accuracy and reliability. 4. Real-Time Display:including shrinking force, contracting force, and shrinkage ratio, allowing for immediate analysis and monitoring. 5. Elimination of Interference Factors: Irrelevant interference factors like friction and cool air are effectively eliminated, ensuring the accuracy of the results. 6. Stable Heating System: The heating system is stable and well-balanced, maintaining consistent and controlled test conditions. 7. Easy Sample Loading: Sample loading is made easy, streamlining the testing process and reducing setup time. 8. High-Resolution Sensors: The system is equipped with high-resolution force transducers and thermometers, guaranteeing precise measurements. 9. Connectivity and Software:(optional) It includes an RS232 port for data connectivity and offers optional professional software for advanced data analysis and reporting capabilities. Standards: ISO 14616, DIN 53369 Main Parameters Force Range 5 N ( or as required) Accuracy ±0.5% Resolution 0.001N Displacement Range 0.1 ~ 95 mm Accuracy ±0.1 mm Temperature Range Ambient ~ 210C Accuracy ±0.5C No. of Specimens 2 Sample size 110*15 mm, L*W Power Supply 220V 50Hz

The FPT-01 Friction and Peel Tester is a versatile and multifunctional device designed for various applications: Measurement of Coefficient of Friction: It accurately measures both static and kinetic coefficients of friction for a wide range of materials, including plastic films, sheets, rubber, paper, paperboard, PP woven bags, fabrics, composites, and more. This capability is valuable for understanding how materials interact with each other and with various surfaces. Delicate Peeling Force Test: The tester can perform delicate peeling force tests on materials such as release paper, adhesive tape, medical adhesives, composite films, and protective films. This feature is essential for assessing the ease of separation between different layers of materials, ensuring product quality and performance. The FPT-01 Friction and Peel Tester is a versatile instrument that serves as a valuable tool for quality control, product development, and research in industries dealing with a wide range of materials, from packaging to medical applications. System Description FPT-01 Friction and peel tester has a fixed loadcell position, with a protection cover. A movable plane is installed firmly to ball lead screw. The sled is to put on sample sticking to the plane, which is then connected to loadcell, with a filament. When performing peeling test, as the force is small, the right sample clamp is stuck to plane, using double side type. Then a separation action is performed to peel the sample and force is recorded during the process. Technical Features FPT-01 Friction and peel tester is a PLC-controlled unit with industrial-grade stability and operates through an intuitive HMI touch screen interface. The precision ball lead screw mechanism ensures consistent speed and displacement control. The system offers two distinct testing methods: one for measuring the coefficient of friction (COF) and another for assessing peeling forces. In COF tests, precise free speed settings are available, while peeling tests consider parameters that influence peeling results, such as initial and tail portions. Other features 1. Real-time data analysis and display, including results and graphical curves. 2. Compliance with various test standards. 3. Integration of a dot matrix micro printer. 4. Inclusion of an advanced peeling program. 5. Optional RS232 and software. Major Standards ISO 8295, ASTM D1894, TAPPI T816, ISO 8510-2, ASTM D4917, ASTM D3330, TAPPI T549 Main Parameters Force Range 5N, 10N, or 30N (or others) Accuracy 0.5 F.S. Sled 200�±1g (or as required) Stroke 500mm Test Speed 1~500mm/min Power 110~220V 50/60Hz

Background Impact strength is a crucial parameter for assessing the quality of plastic films. It plays a significant role in determining a film's ability to withstand external forces and impacts, which can directly affect its cost and performance, especially during transportation and handling. The Falling Dart Impact Test is a traditional and widely accepted method for measuring the impact strength of plastic films. This test helps determine the energy required to cause a plastic film to fail under controlled conditions where a free-falling dart strikes the material's surface. The result of this test provides valuable information about the material's ability to resist impact and can help manufacturers and quality control teams make informed decisions about material selection, product design, and packaging to ensure the durability and integrity of plastic films in various applications. Application FDT-01 Falling Dart Impact Tester is used to measure he resistance performance of plastic films, sheets, and composite films, foils, paper, with less than 1mm thickness. This test indicates material ability to resist external force. The FDT-01 Falling Dart Impact Tester is a specialized testing device designed for measuring the resistance performance of various materials, such as plastic films, sheets, composite films, foils, and paper, provided they are less than 1mm thick. This test is conducted to assess the material's ability to withstand external forces. Standards ASTM D1709, ISO 7765-1, JIS K7124-1, GB/T 9639.1 Technical Features FDT-01 Falling Dart Impact Tester is a PLC controlled unit (industrial level stable) and HMI touch screen operated. Every part of the dart assembly and releasing mechanism are made strictly to standard. By the embedded test program, user just needs to perform test and increase or reduce the weights according to the set parameters. Then after enough number of Fail/Non-Fail tests, the system automatically gives impact result, which is without being manually calculated again. 1. PLC Control and Touch Screen Operation offer stability, ease of use and efficient operation. 2. Two Test Methods (A and B) (Method B is optional) 3. Both Test Button and Foot Switch Are Equipped for safe and easy operation 4. Observation Light helps check sample status during clamping 5. Display of Test Results in Grams and Joules 6. Electromagnetic Suspension and Automatic Falling 7. Sample Pneumatic Clamping 8. Dot Matrix Micro-Printer Embedded for data output 9. Professional Software is Provided as an Optional part Main Parameters Test Method Method A or Method B (optional) Test Range Method A: 50~2000g/Method B: 300~2000g Dart Diameter Method A: 38�±1mm/Method B: 50�±1mm Impact Height 660mm/1500mm Accuracy 0.1g (0.1J) Clamp Pneumatic Clamp Gas Supply 0.6 MPa �¦8 mm PU Tubing Specimen Size > 150 mm x 150 mm Power Supply AC 110~220V 50Hz Dimension Method A: 500*450*1200 mm (LWH)/Method B: 500*450*2200 mm (LWH)

Background Impact resistance plays an important role in the performance of material subjected to regular shocking load or impact load. As this kind of load may cause rupture, cracking or deformation. There are various test procedures to evaluate the impact resistance of a material, such as dart impact, ball impact, pendulum impact, izod, charpy, tensile, etc. Application Falling ball impact tester measures the resistance performance of plates, sheets, and composites, films foils, paper etc. with less than 2mm thickness. By impact test, the material ability to resist external destruction can be indicated. User observes the destruction status of the test specimen after it has been hit by a falling weight that fell from a given testing height. Test Method A steel ball of known mass and diameter is released from a predetermined height, creating a controlled impact force on the test specimen (film or plastic sheet). The impact energy and the resulting damage or deformation are measured and analyzed to assess the material's impact resistance. Factors Influence Result 1. Drop Height: The height from which the steel ball is dropped is a critical parameter that can be adjusted to simulate different impact scenarios. 2. Ball Size and Mass: The size and mass of the steel ball are selected based on the specific testing standards or application requirements. Technical Features FBT-01S is an economic version of ball impact tester, without complicate control and system. It also uses electromagnetic suspension and release, and is equipped with two foot switches too. Sample pneumatic clamping is also the same type and test area as FBT-01. Key Features: 1. Adjustable Impact Height and Various Balls cater to diverse testing scenarios. 2. Electromagnetic Suspension: Employing electromagnetic suspension ensures a controlled and consistent release of the impact ball. 3. Reliable Pneumatic Sample Clamping guarantees that test specimens remain firmly in place throughout testing. 4. User-Friendly Operation: The tester is equipped with two foot switches, simplifying the testing process and enhancing usability. Main Parameters Impact Height 300mm-600mm (can be extended) Ball Diameters(mm) 23, 25, 28.6, 38.1, 50.8(one equipped) Accuracy 0.1g (0.1J) Specimen Clamp Pneumatic Clamp Gas Supply 0.6 MPa �¦8 mm PU Tubing Specimen Size > 150 mm x 150 mm Power Supply AC 110~220V 50Hz

Background Impact resistance plays an important role in the performance of material subjected to regular shocking load or impact load. As this kind of load may cause rupture, cracking or deformation. There are various test procedures to evaluate the impact resistance of a material, such as dart impact, ball impact, pendulum impact, izod, charpy, tensile, etc. Application Falling ball impact tester measures the resistance performance of plates, sheets, and composites, films foils, paper etc. with less than 2mm thickness. By impact test, the material ability to resist external destruction can be indicated. User observes the destruction status of the test specimen after it has been hit by a falling weight that fell from a given testing height. Test Method A steel ball of known mass and diameter is released from a predetermined height, creating a controlled impact force on the test specimen (film or plastic sheet). The impact energy and the resulting damage or deformation are measured and analyzed to assess the material's impact resistance. Factors Influence Result 1. Drop Height: The height from which the steel ball is dropped is a critical parameter that can be adjusted to simulate different impact scenarios. 2. Ball Size and Mass: The size and mass of the steel ball are selected based on the specific testing standards or application requirements. Technical Features The FBT-01 Falling Dart Impact Tester is a system with PLC control (maintaining industrial-grade stability) and is operated via an HMI touch screen interface. Key Features: 1. Precision PLC control and user-friendly touch screen interface 2. Adjustable impact height with a variety of available ball options 3. Display of test results in multiple units 4. Utilizes electromagnetic suspension for automatic ball release 5. Secure sample clamping through pneumatic mechanisms 6. Convenient manual and foot switch operation 7. Equipped with a dot matrix micro-printer 8. Option for advanced professional software (available as an add-on) Main Parameters Impact Height 300mm-600mm (can be extended) Ball Diameters(mm) 23, 25, 28.6, 38.1, 50.8(one equipped) Accuracy 0.1g (0.1J) Specimen Clamp Pneumatic Clamp Gas Supply 0.6 MPa 8 mm PU Pipe Specimen Size > 150 mm x 150 mm Power Supply AC 110~220V 50Hz

Background Given the extensive applications of mop materials in diverse settings, including homes, offices, and industries, rigorous quality testing is essential. While their ease of washing and high absorbency are valuable traits, consistent performance over time is vital. Quality testing ensures mops retain their absorbency and durability, upholding their effectiveness in tasks such as cleaning kitchen surfaces, windows, and furniture. This process identifies and addresses potential issues, maintaining the reliability and functionality of mops across various uses. Application COF-S1 is a specialized coefficient of friction tester for mop and cleaning materials like microfiber mop pads, sponge mops with foam blocks (cellulosic, rubber, or plastic). Friction varies based on usage for liquids, dust, and dry surfaces. The mop's friction coefficient affects its cleaning efficiency and usability. Excessive friction raises labor intensity, while too little hampers cleaning, thus requiring a balanced coefficient for optimal performance. Formula COF is determined by dividing the force needed to move one surface across another by the force perpendicular to the surfaces. It has two kinds: Static and Kinetic. Static COF �µs is measure of force required to begin movement. Kinetic COF �µd is measure of force required to maintain movement. Test Method Fix the sample cloth to its aluminum or plastic frame, then the total assembled part is placed under a certain weight. The block, together with the sample and its frame, is pulled at a speed of 500mm/min, for 500mm distance. The static and kinetic coefficient of friction are recorded. Technical Features COF-S1 Mop Cloth Coefficient of Friction Tester is a PLC controlled and HMI screen operated equipment with industrial level stability. Equipped with user designated test range, and with variable test speed, itâ??s ideal for mop manufacturers to control quality and develop new product. Key Parameters (customization Available) Force Range 100N Resolution 0.5%FS Speed Adjustable 1~1000mm/min Speed Accuracy 0.1mm/min Sled 100*100mm Sled Weight 225g�±1g Total Sample Weight 520g�±1g Stroke 500mm Loadcell Height 50mm Test Mode 5 groups Power 110~220V

Application The CLRT-01 Carbon Dioxide Volume Tester is a crucial tool in the beverage industry, focusing on gauging carbonation levels, which significantly impact the bubbly and sensory qualities of drinks, thus influencing product excellence and customer contentment. Specially crafted for CO2 volume assessment, the CLRT-01 employs an automated process to uncover the connection between pressure and temperature, a pivotal factor in thorough beverage quality analysis. By seamlessly merging these elements, it offers a profound understanding of carbonation dynamics, granting manufacturers the ability to maintain consistency, adapt formulations, and provide effervescence that resonates with consumer preferences and brand achievement. Automatic Testing and Shaking The tester automates the traditional manual process: Piercing the bottle cap â?? Opening the vent valve to release pressure â?? Closing the vent valve â?? Vigorously vibrating for 40 seconds â?? Recording the stabilized MPa pressure (while measuring liquid temperature) â?? Obtaining the carbon dioxide gas capacity test results. Technical Features 1.This unit is under precise PLC control (at an industrial-grade stability level) and operated through an HMI touch screen interface. 2.Agitating the sample bottle is achieved using a servo motor and gearbox transmission mechanism. 3.The design incorporates anti-leak features and includes accurate temperature and pressure measurement. 4.The process involves automated piercing and shaking. 5.Displacement and speed during piercing are controlled for accuracy. 6.The shaking parameters, including frequency and duration, can be customized. 7.Test results are guaranteed accurate due to the implementation of a highprecision pressuresensor. 8.Real-time temperature display is enabled by a precision temperature sensor. 9.Post-test, the carbonation volume is automatically and presented. 10.Designed to prevent leaks, this versatile tester is suitable for both bottles and cans. 11.(Optional) A microprinter can be incorporated for additional functionality. 12.(Optional) The inclusion of an RS 232 port and professional software provides further versatility. Main Parameters Test Range 0~1MPa Resolution 0.01KPa Shaking Speed Adjustable Piercing Speed 5mm/s (other available) Sample Height â?¤ 350mm (other available) Temp. range 0 ~ 30 Shaking time 40s (other available) Resolution 0.1