 نسخه الکترونیکی این سند اخرین نسخه آن است و مسئولیت کنترل نسخه چاپی با این سند بر عهده خواننده آن می باشد.
تمامی حقوق معنوی و مادی این مدرک متعلق به شرکت پایش سلامت اسیا می باشد. و هر گونه کپی برداری از ان پیگرد قانونی دارد. |
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| انتخاب منابع ارزیابی انطباق | رویکرد | CAS/0/2/1 | شماره سند | |
| رنگ سفید اسناد / قرمز فرمهای دریافتی/ ابی فرمهای ارسالی | راهنمای دکمه های انتهایی صفحه | |||
| تاریخ | تایید | بازنگری | نویسنده | شماره |
| شهریور ۱۴۰۲ | هیات مدیره | دکتر شیدا بزمی | دکترعلیرضامسعودنیا | ۱ |
Take the guesswork out of inspections by showing your team exactly what type of answer you want. Add logic so only the questions that need to be answered show up, and enable repeated sections so inspectors can use the same set of questions as many times as they need to when inspecting different items.
Additionally, with digital inspections, you can easily track and store all your inspection data in one central location. This makes it easy to access and analyze the information later on. You can also set up notifications to alert you when inspections are due or when any issues are found during the inspection process. Overall, digital inspections can help streamline and improve the efficiency of your inspection process.
Test-oriented inspection equipment
Test-oriented inspection equipment refers to tools and devices used to conduct tests and inspections on various products or materials to ensure they meet quality standards and specifications. This equipment is designed to accurately measure, analyze, and evaluate the characteristics and performance of the items being tested. Examples of test-oriented inspection equipment include calipers, micrometers, gauges, thermometers,, and hardness testers. These tools help manufacturers and quality control professionals identify any defects or deviations in the products and make necessary adjustments to improve their overall quality
.List of industrial inspection equipment and its implementation method
1. Ultrasonic Testing Equipment: Used to detect internal defects in materials such as cracks, voids, and inclusions. Implementation method includes scanning the surface of the material with the ultrasonic probe and analyzing the reflected waves to identify any defects.
2. X-ray Inspection Equipment: Used to inspect the internal structure of materials and products for defects such as cracks, voids, and inclusions. Implementation method involves exposing the material to X-rays and capturing the image on a detector for analysis.
3. Visual Inspection Equipment: Includes tools such as borescopes, endoscopes, and cameras for visually inspecting the surface and internal features of materials and products. Implementation method involves inserting the inspection tool into the material or product and viewing the images on a monitor for analysis.
4. Magnetic Particle Inspection Equipment: Used to detect surface and near-surface defects in materials such as cracks and discontinuities. Implementation method includes applying a magnetic field to the material and then applying magnetic particles which will accumulate near any defects, making them visible for inspection.
5. Dye Penetrant Inspection Equipment: Used to detect surface defects in materials such as cracks and porosity. Implementation method involves applying a dye penetrant to the surface of the material, allowing it to seep into any defects, and then applying a developer to make the defects visible for inspection.
6. Eddy Current Testing Equipment: Used to detect surface and near-surface defects in conductive materials. Implementation method involves passing an alternating current through a coil to generate eddy currents in the material, and analyzing changes in the eddy currents caused by defects.
7. Infrared Thermography Equipment: Used to detect defects in materials and products by measuring temperature variations. Implementation method involves scanning the surface of the material with an infrared camera and analyzing the thermal images to identify any anomalies.
8. Laser Scanning Equipment: Used for dimensional inspection and reverse engineering of products. Implementation method involves scanning the surface of the product with a laser scanner to create a 3D model for analysis and comparison with the original design.
The list of industrial technical inspection field equipment and its execution method by the impartial inspection company
Some examples of industrial technical inspection field equipment and their execution methods by an impartial inspection company include:
1. Ultrasonic Testing Equipment: This equipment is used to detect flaws and measure the thickness of materials by sending high-frequency sound waves through the material. The execution method involves positioning the transducer on the surface of the material and interpreting the reflected waves to identify any defects.
2. Magnetic Particle Testing Equipment: This equipment is used to detect surface and near-surface flaws in ferromagnetic materials. The execution method involves applying a magnetic field to the material and then applying magnetic particles to the surface. Any defects will cause the particles to gather at the flaw location, making it visible to the inspector.
3. Dye Penetrant Testing Equipment: This equipment is used to detect surface defects in non-porous materials. The execution method involves applying a liquid dye penetrant to the surface of the material, allowing it to seep into any surface defects. After a waiting period, the excess penetrant is removed, and a developer is applied to highlight any defects.
4. Visual Inspection Equipment: This equipment includes tools such as borescopes, cameras, and magnifying lenses for visually inspecting the surface and internal components of equipment. The execution method involves a thorough visual examination of the material or component to identify any visible defects or irregularities.
5. Eddy Current Testing Equipment: This equipment is used to detect surface and near-surface defects in conductive materials. The execution method involves passing an alternating current through a coil to generate an electromagnetic field. Any defects in the material will disrupt the field, causing a change in the coil’s impedance, which can be measured and interpreted by the inspector.
Non-Destructive Testing
Non-Destructive Testing (NDT) refers to a wide range of analysis techniques used in science and industry to evaluate the properties of a material, component, or system without causing damage. These techniques are used to detect surface and subsurface defects, assess structural integrity, measure material properties, and evaluate the quality of a product or material. Some common NDT methods include ultrasonic testing, radiography, magnetic particle testing, liquid penetrant testing, and visual inspection. NDT is important for ensuring the safety, reliability, and quality of products and structures without the need for destructive testing methods that would render the material unusable.
Destructive tests
Destructive tests are tests that involve breaking or damaging a material, component, or product in order to evaluate its mechanical properties, performance, or durability. These tests are often used to determine the ultimate strength, ductility, and other important characteristics of a material or product. Examples of destructive tests include tensile testing, impact testing, and hardness testing.