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Custom Manufactured Parts, Assemblies, Plastic Mold, Rubber Molding, Metal Casting, CNC Machining, Turning, Milling, Electrical Electronic Optical Assembly PCBA Parçe & Meclîs & Berhemên Xweserî Çêkirî Read More Qalibên Plastîk & Gomûk û Molding Read More Casting and Machining Read More Extrusions, Berhemên Extruded Read More Stampings & Sheet Metal Fabrication Read More Metal Forging & Powder Metalurgy Read More Têl & Çêkirina Biharê Read More Çêkirin & Şêwekirin Glass & Seramîk Read More Zêdekirin û Hilberîna Bilez Read More Hilberîna Materyalên Pêkhatî & Pêkhatî Read More Pêvajoyên Tevlîbûn & Civîn & Çêkirin We produce parts and assemblies for you and offer the following manufacturing processes: • Plastic and rubber moulds and moulded parts. Injection moulding, thermoforming, thermoset moulding, vacuum forming, blow moulding, rotational moulding, pour moulding, insert moulding and others. • Plastic, rubber and metal extrusions • Ferrous and nonferrous castings and machined parts produced by milling and turning techniques, Swiss-type machining. • Powder metallurgy parts • Metal and nonmetal stampings, sheet metal forming, welded sheet metal assemblies • Cold and hot forging • Wires, welded wire assemblies, wire forming • Various types of springs, spring forming • Gear manufacturing, gearbox, coupling, worm, speed reducer, cylinder, transmission belts, transmission chains, transmission components • Custom tempered and bulletproof glass compliant with NATO and military standards • Balls, bearings, pulleys and pulley assemblies • Valves and pneumatic components such as O-ring, washer and seals • Glass and ceramic parts and assemblies, vacuum proof and hermetic components, metal-ceramic and ceramic-ceramic bonding. • Various types of mechanical, optomechanical, electromechanical, optoelectronic assemblies. • Metal-rubber, metal-plastic bonding • Pipe and tube, pipe forming, bending and custom pipe assemblies, bellow manufacturing. • Fiberglass manufacturing • Welding using various techniques such as spot welding, laser welding, MIG, TIG. Ultrasonic welding for plastic parts. • Vast variety of surface treatments and surface finishes such as surface conditioning to enhance adhesion, depositing thin oxide layer to enhance adhesion of coating, sand blasting, chem-film, anodizing, nitriding, powder coating, spray coating, various advanced metallization and coating techniques including sputtering, electron beam, evaporation, plating, hard coatings such as diamond like carbon (DLC) or titanium for cutting and drilling tools. • Marking and labeling, laser marking on metal parts, printing on plastic and rubber parts Download brochure for Common Mechanical Engineering Terms used by Designers and Engineers We build products according to your particular specifications and requirements. In order to offer you the best quality, delivery and prices, we manufacture products globally in China, India, Taiwan, Philippines, South Korea, Malaysia, Sri Lanka, Turkey, USA, Canada, Germany, UK and Japan. This makes us much stronger and globally more competitive than any other custom manufacturer. Our products are manufactured in ISO9001:2000, QS9000, ISO14001, TS16949 certified environments and possess CE, UL mark and meet other industry standards. Once we are appointed for your project, we can take care of the entire manufacturing, assembly, testing, qualification, shipping & customs as you wish. If you prefer, we can warehouse your parts, assemble custom kits, print and label your company name & brand and drop ship to your customers. In other words, we can be your warehousing and distribution center as well if preferred. Since our warehouses are located near major seaports, it gives us logistical advantage. For example, when your products arrive at a major USA seaport, we can transport it directly to a nearby warehouse where we can store, assemble, make kits, relabel, print, package according to your choice and drop ship to your customers. We not only supply products. Our company works on custom contracts where we come to your site, evaluate your project on site and develop a project proposal custom designed for you. We then send our experienced team to implement the project. More information about our engineering work can be found on http://www.ags-engineering.com -We take small projects as well as large projects at industrial scale. As a first step, we can connect you either by phone , teleconferencing or MSN messenger to our expert team members, so you can communicate directly to an expert, ask questions and discuss your project. Call us and if needed we will come and visit you. RÛPERA BERÊ

Mechanical Testing Instruments - Tension Tester - Torsion Test Machine - Bending Tester - Impact Test Device - Concrete Tester - Compression Testing Machine - H Amûrên Testê Mekanîkî Among the large number of MECHANICAL TEST INSTRUMENTS we focus our attention to the most essential and popular ones: IMPACT TESTERS, CONCRETE TESTERS / SCHMIDT HAMMER, TENSION TESTERS, COMPRESSION TESTING MACHINES, TORSION TEST EQUIPMENT, FATIGUE TEST MACHINE, THREE & FOUR POINT BENDING TESTERS, COEFFICIENT OF FRICTION TESTERS, HARDNESS & THICKNESS TESTERS, SURFACE ROUGHNESS TESTERS, VIBRATION METERS, TACHOMETERS, PRECISION ANALYTICAL BALANCE. We offer our customers quality brands such as ELCOMETER, SADT, SINOAGE for under list prices. Please choose from the downloadable catalogs below the brand name and model number of the equipment you need and tell us whether you want a brand new or refurbished / used equipment: AMETEK-LLOYD Instruments Materials Testing (Versatile Materials Testing Equipment, Universal Test Machines, Tensile Strength, Compressibility, Hardness, Elasticity, Peeling, Adhesion...etc.) ELCOMETER Inspection Equipment Catalog ( Physical Test Equipment , Concrete Inspection Equipment, Concrete Test Hammers, Fineness Of Grind/Dispersion , Density & Specific Gravity , Viscosity & Flow Measurement , Film Application & Test Charts , Drying Time & Permeability , Washability & Abrasion , Hardness & Scratch Resistance , Elasticity, Bend & Impact Testers , Flash Point ) HAIDA Adhesive Tape Peel Test Machine HAIDA Computerized Universal Test Machine with Extensometer HAIDA Computerized Universal Test Machine with Large Capacity (Double Column) HAIDA Computer Servo Tensile Test Machine HAIDA Desktop Tensile Test Machine HAIDA Double-Column Universal Testing Machine HAIDA Electro-Hydraulic Universal Testing Machine HAIDA Extra - Height Tensile Test Machine HAIDA Tensile Test Machines HAIDA Universal Testing Machine HAIDA Universal Test Machine HAIDA Universal Test Machine with Temperature Chamber INSTRON Compression and Tension Test Instruments SADT-SINOAGE Brand Metrology and Test Equipment, please CLICK HERE. Here you will find some of these testing equipment such as concrete testers and surface roughness tester. Let us examine these test devices in some detail: SCHMIDT HAMMER / CONCRETE TESTER : This test instrument, also sometimes called a SWISS HAMMER or a REBOUND HAMMER, is a device to measure the elastic properties or strength of concrete or rock, mainly surface hardness and penetration resistance. The hammer measures the rebound of a spring-loaded mass impacting against the surface of the sample. The test hammer will hit the concrete with a predetermined energy. The hammer’s rebound depends on the hardness of the concrete and is measured by the test equipment. Taking a conversion chart as a reference, the rebound value can be used to determine the compressive strength. The Schmidt hammer is an arbitrary scale ranging from 10 to 100. Schmidt hammers come with several different energy ranges. Their energy ranges are: (i) Type L-0.735 Nm impact energy, (ii) Type N-2.207 Nm impact energy; and (iii) Type M-29.43 Nm impact energy. Local variation in the sample. To minimize local variation in the samples it is recommended to take a selection of readings and take their average value. Prior to testing, the Schmidt hammer needs to be calibrated using a calibration test anvil supplied by the manufacturer. 12 readings should be taken, dropping the highest and lowest, and then taking the average of the ten remaining readings. This method is considered an indirect measurement of the strength of the material. It provides an indication based on surface properties for comparison between samples. This test method for testing concrete is governed by ASTM C805. On the other hand, the ASTM D5873 standard describes the procedure for testing of rock. Inside of our SADT brand catalog you will find the following products: DIGITAL CONCRETE TEST HAMMER SADT Models HT-225D/HT-75D/HT-20D - The SADT Model HT-225D is an integrated digital concrete test hammer combining data processor and test hammer into a single unit. It is widely used for non destructive quality testing of concrete and building materials. From its rebound value, the compressive strength of concrete can be calculated out automatically. All test data can be stored in memory and transferred to PC by USB cable or wirelessly by Bluetooth. The models HT-225D and HT-75D have measuring range of 10 – 70N/mm2, whereas the model HT-20D has only 1 – 25N/mm2. The impact energy of HT-225D is 0.225 Kgm and is suitable for testing ordinary building and bridge construction, the impact energy of HT-75D is 0.075 Kgm and is suitable for testing small and impact-sensitive parts of concrete and artificial brick, and finally the impact energy of HT-20D is 0.020Kgm and suitable for testing mortar or clay products. IMPACT TESTERS: In many manufacturing operations and during their service lives, many components need to be subjected to impact loading. In the impact test, the notched specimen is placed in an impact tester and broken with a swinging pendulum. There are two major types of this test: The CHARPY TEST and the IZOD TEST. For the Charpy test the specimen are supported at both ends, whereas for the Izod test they are supported only at one end like a cantilever beam. From the amount of swing of the pendulum, the energy dissipated in breaking the specimen is obtained, this energy is the impact toughness of the material. Using the impact tests, we can determine the ductile-brittle transition temperatures of materials. Materials with high impact resistance generally have high strength and ductility. These tests also reveal the sensitivity of a material’s impact toughness to surface defects, because the notch in the specimen can be considered a surface defect. TENSION TESTER : The strength-deformation characteristics of materials are determined using this test. Test specimen are prepared according to ASTM standards. Typically, solid and round specimens are tested, but flat sheets and tubular samples may also be tested using tension test. The original length of a specimen is the distance between gage marks on it and is typically 50 mm long. It is denoted as lo. Longer or shorter lengths can be used depending on the specimens and products. The original cross-sectional area is denoted as Ao. The engineering stress or also called nominal stress is then given as: Sigma = P / Ao And the engineering strain is given as: e = (l – lo) / lo In the linear elastic region, the specimen elongates proportionately to the load up to the proportional limit. Beyond this limit, even though not linearly, the specimen will continue to deform elastically up to the yield point Y. In this elastic region, the material will return to its original length if we remove the load. Hooke’s Law applies in this region and gives us the Young’s Modulus: E = Sigma / e If we increase the load and move beyond the yield point Y, the material begins to yield. In other words, the specimen begins to undergo plastic deformation. Plastic deformation means permanent deformation. The cross-sectional area of the specimen decreases permanently and uniformly. If specimen is unloaded at this point, the curve follows a straight line downward and parallel to the original line in the elastic region. If the load is further increased, the curve reaches a maximum and begins to decrease. The maximum stress point is called the tensile strength or ultimate tensile strength and is denoted as UTS. The UTS can be interpreted as the overall strength of materials. When load is greater than the UTS, necking occurs on the specimen and the elongation between gage marks is no longer uniform. In other words, the specimen becomes really thin at the location where necking occurs. During necking, the elastic stress drops. If the test is continued, the engineering stress drops further and the specimen fractures at the necking region. The stress level at fracture is the fracture stress. The strain at point of fracture is an indicator of ductility. The strain up to the UTS is referred to as uniform strain, and the elongation at fracture is referred to as total elongation. Elongation = ((lf – lo) / lo) x 100 Reduction of Area = ((Ao – Af) / Ao) x 100 Elongation and reduction of area are good indicators of ductility. COMPRESSION TESTING MACHINE ( COMPRESSION TESTER ) : In this test, the specimen is subjected to a compressive load contrary to the tensile test where the load is tensile. Generally, a solid cylindrical specimen is placed between two flat plates and compressed. Using lubricants at the contact surfaces, a phenomenon known as barreling is prevented. Engineering strain rate in compression is given by: de / dt = - v / ho, where v is die speed, ho original specimen height. True strain rate on the other hand is: de = dt = - v/ h, with h being the instantaneous specimen height. To keep the true strain rate constant during the test, a cam plastometer thru a cam action reduces the magnitude of v proportionally as the specimen height h decreases during the test. Using the compression test ductilities of materials are determined by observing cracks formed on barreled cylindrical surfaces. Another test with some differences in the die and workpiece geometries is the PLANE-STRAIN COMPRESSION TEST, which gives us the yield stress of the material in plane strain denoted widely as Y’. Yield stress of materials in plane strain can be estimated as: Y’ = 1.15 Y TORSION TEST MACHINES (TORSIONAL TESTERS) : The TORSION TEST is another widely used method for determining material properties. A tubular specimen with a reduced mid-section is used in this test. Shear stress, T is given by: T = T / 2 (Pi) (square of r) t Here, T is the applied torque, r is the mean radius and t is the thickness of the reduced section in the middle of the tube. Shear strain on the other hand is given by: ß = r Ø / l Here l is the length of the reduced section and Ø is the twist angle in radians. Within the elastic range, the shear modulus (modulus of rigidity) is expressed as: G = T / ß The relation between shear modulus and the modulus of elasticity is: G = E / 2( 1 + V ) The torsion test is applied to solid round bars at elevated temperatures to estimate the forgeability of metals. The more twists the material can withstand prior to failure, the more forgeable it is. THREE & FOUR POINT BENDING TESTERS : For brittle materials, the BEND TEST (also called FLEXURE TEST) is suitable. A rectangularly shaped specimen is supported at both ends and a load is applied vertically. The vertical force is applied at either one point as in the case of three point bending tester, or at two points as in the case of a four point test machine. The stress at fracture in bending is referred to as the modulus of rupture or transverse rupture strength. It is given as: Sigma = M c / I Here, M is the bending moment, c is one-half of the specimen depth and I is the moment of inertia of the cross-section. The magnitude of stress is the same in both three and four-point bending when all other parameters are kept constant. The four-point test is likely to result in a lower modulus of rupture as compared to the three-point test. Another superiority of the four-point bending test over the three point bending test is that its results are more consistent with less statistical scattering of values. FATIGUE TEST MACHINE: In FATIGUE TESTING, a specimen is subjected repeatedly to various states of stress. The stresses are generally a combination of tension, compression and torsion. The test process can be resembled to bending a piece of wire alternately in one direction, then the other until it fractures. The stress amplitude can be varied and is denoted as “S”. The number of cycles to cause total failure of the specimen is recorded and is denoted as “N”. Stress amplitude is the maximum stress value in tension and compression to which the specimen is subjected. One variation of the fatigue test is performed on a rotating shaft with a constant downward load. The endurance limit (fatigue limit) is defined as the max. stress value the material can withstand without fatigue failure regardless of the number of cycles. Fatigue strength of metals is related to their ultimate tensile strength UTS. COEFFICIENT OF FRICTION TESTER : This test equipment measures the ease with which two surfaces in contact are able to slide past one another. There are two different values associated with the coefficient of friction, namely the static and kinetic coefficient of friction. Static friction applies to the force necessary to initialize motion between the two surfaces and kinetic friction is the resistance to sliding once the surfaces are in relative motion. Appropriate measures need to be taken prior to testing and during testing to ensure freedom from dirt, grease and other contaminants that could adversely affect test results. ASTM D1894 is the main coefficient of friction test standard and is used by many industries with different applications and products. We are here to offer you the most suitable test equipment. If you need a custom set-up specifically designed for your application, we can modify existing equipment accordingly in order to meet your requirements and needs. HARDNESS TESTERS : Please go to our related page by clicking here THICKNESS TESTERS : Please go to our related page by clicking here SURFACE ROUGHNESS TESTERS : Please go to our related page by clicking here VIBRATION METERS : Please go to our related page by clicking here TACHOMETERS : Please go to our related page by clicking here For details and other similar equipment, please visit our equipment website: http://www.sourceindustrialsupply.com CLICK Product Finder-Locator Service RÛPERA BERÊ

Pneumatic Hydraulic & Vacuum Tools, Air Tool, Hydraulic Powered Tools, Air Screwdrivers, Air Drills, Pneumatic Nail Guns, Air Die Grinders,Hydraulic Pipe Cutter Amûrên ji bo Hîdraulîk & Pneumatîk & Vacuum We also supply widely used industrial tools for pneumatic, hydraulic and vacuum systems. PNEUMATIC TOOLS (also called AIR TOOLS or AIR-POWERED TOOLS or PNEUMATIC-POWERED TOOLS are types of power tools driven by compressed air, supplied by air compressors. Pneumatic tools can also be driven by compressed carbon dioxide (CO2) stored in small cylinders allowing portability and use where no compressed air lines are available. Pneumatic tools are safer to run and easier to maintain than electric power tool equivalents. Pneumatic tools also have a higher power-to-weight ratio, allowing a smaller, lighter tool to accomplish the same task. General grade pneumatic tools with short life span are generally less expensive. Both disposable as well as industrial grade pneumatic tools with long life span are available. Generally speaking, pneumatic tools are cheaper than the equivalent electric-powered tools. Air tools are becoming more and more popular in the DIY (Do it yourself) market. HYDRAULIC-POWERED TOOLS on the other hand are generally more powerful tools used for applications that require higher pressures and forces. Liquids are much much less compressible than gases and that is the reason why hydraulic powered tools are able to supply such large forces. INDUSTRIAL VACUUM TOOLS offered are mostly manipulators, grippers, holders, lifters used in handling, moving, removing parts and components in industrial settings. Vacuum is also used in packaging to remove air from inside packages to extend the shelf life of products and protect them from moisture, air and early corrosion and decay. We supply both off-shelf and custom manufactured pneumatic, hydraulic and vacuum tools. Here is a list of some common tools: AIR SCREWDRIVERS, ROUTERS AIR RATCHET AIR & HYDRAULIC DRILLS PNEUMATIC NAIL GUN AIR & HYDRAULIC HAMMERS RIVETER & RIVETING HAMMER AIR GUNS and NOZZLES SANDBLASTER AIRBRUSH PAINT SPRAYER AIR CAULK GUNS AIR DIE GRINDERS AIR SANDER AIR BEVELERS AIR CUT-OFF TOOLS SWIVEL CONNECTORS AIR KNIVES PNEUMATIC SLIDES AIR CANNONS AIR AMPLIFIERS AIR CONVEYORS HYDRAULIC & PNEUMATIC TORQUE WRENCH HYDRAULIC PRESSES HYDRAULIC PIPE CUTTERS HYDRAULIC PULLER HYDRAULIC BOLTING TOOLS HYDRAULIC WORKHOLDING DEVICES VACUUM MANIPULATORS and GRIPPERS VACUUM LIFTERS VACUUM PACKAGING TOOLS CUSTOM SPECIALTY TOOLS Click links below to download our relevant brochures: - Air Tool Kits - Air Tools Accessories and Special Industrial Pneumatic Tools - Air Nailers and Staplers - Air Spray Guns - Air Brushes - Air Guns, Hoses, Connectors, Splitters and Accessories - DIY Air Tools - DIY Air Tools Assortment & Wet Air Tools - Oil-Less Mini Air Compressors - Private Label Pneumatic Air Blow Guns (We can put your company name, brand, logo, label on these if you wish) - Private Label Pneumatic Compressed Air Tools (We can put your company name, brand, logo, label on these if you wish) - Professional Air Tools Part-1 - Professional Air Tools Part-2 - Professional Air Tools Part-3 - Professional Air Tools Assortment CLICK Product Finder-Locator Service RÛPERA BERÊ

Optical Displays, Screen, Monitors, Touch Panel Manufacturing Çêkirin & Civîna Dîmender, Dîmender, Çavdêrên Optîkî Ji bo BERNAMEYA HEVKARÎYA DESIGN a me broşurê dakêşin CLICK Product Finder-Locator Service RÛPERA BERÊ

Electron Beam Machining, EBM, E-Beam Machining & Cutting & Boring, Custom Manufacturing of Parts - AGS-TECH Inc. - NM - USA EBM Machining & Electron Beam Machining In ELECTRON-BEAM MACHINING (EBM) we have high-velocity electrons concentrated into a narrow beam which are directed toward the work piece, creating heat and vaporizing the material. Thus EBM is a kind of HIGH-ENERGY-BEAM MACHINING technique. Electron-Beam Machining (EBM) can be used for very accurate cutting or boring of a variety of metals. Surface finish is better and kerf width is narrower in comparison to other thermal-cutting processes. The electron beams in EBM-Machining equipment are generated in an electron beam gun. The applications of Electron-Beam Machining are similar to those of Laser-Beam Machining, except that EBM requires a good vacuum. Thus these two processes are classified as electro-optical-thermal processes. The workpiece to be machined with EBM process is located under the electron beam and is kept under vacuum. The electron beam guns in our EBM machines are also provided with illumination systems and telescopes for alignment of the beam with the workpiece. Workpiece is mounted on a CNC table so that holes of any shape can be machined using the CNC control and beam deflection functionality of the gun. To achieve the fast evaporation of the material, the planar density of the power in the beam must be as high as possible. Values up to 10exp7 W/mm2 can be achieved at the spot of impact. The electrons transfer their kinetic energy into heat in a very small area, and the material impacted by the beam is evaporated in a very short time. The molten material at the top of the front, is expelled from the cutting zone by the high vapor pressure at the lower parts. EBM equipment is built similarly to electron beam welding machines. Electron-beam machines usually utilize voltages in the range of 50 to 200 kV to accelerate electrons to about 50 to 80% of the speed of light (200,000 km/s). Magnetic lenses whose function is based on Lorentz forces are used to focus the electron beam to the surface of the workpiece. With the help of a computer, the electromagnetic deflection system positions the beam as needed so holes of any shape can be drilled. In other words, the magnetic lenses in Electron-Beam-Machining equipment shape the beam and reduce the divergence. Apertures on the other hand allow only the convergent electrons to pass and capture the divergent low energy electrons from the fringes. The aperture and the magnetic lenses in EBM-Machines thus improve the quality of the electron beam. The gun in EBM is used in pulsed mode. Holes can be drilled in thin sheets using a single pulse. However for thicker plates, multiple pulses would be needed. Switching pulse durations of as low as 50 microseconds to as long as 15 miliseconds are generally used. To minimize electron collisions with air molecules resulting in scattering and keep contamination to a minimum, vacuum is used in EBM. Vacuum is difficult and expensive to produce. Especially obtaining good vacuum within large volumes and chambers is very demanding. Therefore EBM is best suited for small parts that fit into reasonably sized compact vacuum chambers. The level of vacuum within the EBM’s gun is in the order of 10EXP(-4) to 10EXP(-6) Torr. The interaction of the electron beam with the work piece produces X-rays which pose health hazard, and therefore well trained personnel should operate EBM equipment. Generally speaking, EBM-Machining is used for cutting holes as small as 0.001 inch (0.025 millimetre) in diameter and slots as narrow as 0.001 inch in materials up to 0.250 inch (6.25 millimetres) thick. Characteristic length is the diameter over which the beam is active. Electron beam in EBM may have a characteristic length of tens of microns to mm depending on degree of focusing of the beam. Generally, the high-energy focused electron beam is made to impinge on the workpiece with a spot size of 10 – 100 microns. EBM can provide holes of diameters in the range of 100 microns to 2 mm with a depth up to 15 mm, i.e., with a depth/diameter ratio of around 10. In case of defocused electron beams, power densities would drop as low as 1 Watt/mm2. However in case of focused beams the power densities could be increased to tens of kW/mm2. As a comparison, laser beams can be focused over a spot size of 10 – 100 microns with a power density as high as 1 MW/mm2. Electrical discharge typically provides the highest power densities with smaller spot sizes. Beam current is directly related to the number of electrons available in the beam. Beam current in Electron-Beam-Machining can be as low as 200 microamperes to 1 ampere. Increasing the EBM’s beam current and/or pulse duration directly increases the energy per pulse. We use high-energy pulses in excess of 100 J/pulse to machine larger holes on thicker plates. Under normal conditions, EBM-machining offers us the advantage of burr-free products. The process parameters directly affecting the machining characteristics in Electron-Beam-Machining are: • Acceleration voltage • Beam current • Pulse duration • Energy per pulse • Power per pulse • Lens current • Spot size • Power density Some fancy structures can also be obtained using Electron-Beam-Machining. Holes can be tapered along the depth or barrel shaped. By focusing the beam below the surface, reverse tapers can be obtained. A wide range of materials like steel, stainless steel, titanium and nickel super-alloys, aluminum, plastics, ceramics can be machined using e-beam-machining. There could be thermal damages associated with EBM. However, the heat-affected zone is narrow due to short pulse durations in EBM. The heat-affected zones are generally around 20 to 30 microns. Some materials such as aluminum and titanium alloys are more readily machined compared to steel. Furthermore EBM-machining does not involve cutting forces on the work pieces. This enables machining of fragile and brittle materials by EBM without any significant clamping or attaching as is the case in mechanical machining techniques. Holes can also be drilled at very shallow angles like 20 to 30 degrees. The advantages of Electron-Beam-Machining: EBM provides very high drilling rates when small holes with high aspect ratio are drilled. EBM can machine almost any material regardless of its mechanical properties. No mechanical cutting forces are involved, thus work clamping, holding and fixturing costs are ignorable, and fragile/brittle materials can be processed without problems. Heat affected zones in EBM are small because of shorte pulses. EBM is able of providing any shape of holes with accuracy by using electromagnetic coils to deflect electron beams and the CNC table. The disadvantages of Electron-Beam-Machining: Equipment is expensive and operating and maintaining vacuum systems requires specialized technicians. EBM requires significant vacuum pump down periods for attaining required low pressures. Even though heat affected zone is small in EBM, the recast layer formation occurs frequently. Our many years of experience and know-how helps us to take advantage of this valuable equipment in our manufacturing environment. CLICK Product Finder-Locator Service RÛPERA BERÊ

We supply custom manufactured and off-shelf jigs, fixtures and workholding tools for industrial applications, manufacturing lines, production lines, test and inspection lines, machine shops, R&D labs.......etc. Jigs, Fixture, Amûr, Çareseriyên Karker, Mold Components Manufacturing We offer custom manufactured and off-shelf jigs, fixtures and toolings for your workshop, factory, plant lab or other facility. The types of jigs you can purchase from us are: - Template Jig - Plate Jig - Angle-Plate Jig - Channel Jig - Diameter Jig - Leaf Jig - Ring Jig - Box Jig The types of fixtures we can supply you are: - Turning Fixtures - Milling Fixtures - Broaching Fixtures - Grinding Fixtures - Boring Fixtures - Tapping Fixtures - Duplex Fixtures - Welding Fixtures - Assembly Fixtures - Drilling Fixtures - Indexing Fixtures Some categories of industrial machine tools we manufacture and ship include: - Press tools and dies, shears - Extrusion dies - Molds, molding and casting tools - Forming tools - Shaping tools - Drilling, cutting, broaching, hobbing tools - Grinding tools - Machining, milling, turning tools - Holding and clamping tools CLICK ON BLUE TEXT BELOW TO DOWNLOAD CATALOGS & BROCHURES: EDM Tooling - Workholding Catalog Includes EDM Tooling System and Elements, EROWA Link, 3R-Link, UniClamp, Square Clamp, RefTool Holder, PIN Holder System, Clamping Elements, Swivel Block and Vises, CentroClamp, EDM Spare Parts....etc. Hose Crimping Machines and Tools We private label these with your brand name and logo if you wish. Crimp development team can assist you with the design and development of tooling for all of your crimping requirements. Hose Endforming Machines and Tools We private label these with your brand name and logo if you wish. Tool development team can assist you with the design and development of tooling for all of your end-forming tool requirements. Plastic Mold Components Catalog Here you will find off-shelf components, products that you can order and use in manufacturing your molds. These products are ideal for mold makers. Example products you can find here are ejector pins, slide units, pressure plugs, guide pins, sprue bushings, slide holding devices, wear plates, ejector sleeves.....etc. Private Label Auto Glass Repair and Replacement Systems We can private label these hand tools if you wish. In other words, we can put your company name, brand and label on them. This way you can promote your brand by reselling these to your customers. Private Label Hand Tools for Every Industry We can private label these hand tools if you wish. In other words, we can put your company name, brand and label on them. This way you can promote your brand by reselling these to your customers. Private Label Hand Tools - Hand Tool Cabinets We can private label these hand tools if you wish. In other words, we can put your company name, brand and label on them. This way you can promote your brand by reselling these to your customers. Private Label Power Tools for Every Industry We can private label these hand tools if you wish. In other words, we can put your company name, brand and label on them. This way you can promote your brand by reselling these to your customers. Wire EDM Tooling - Workholding Catalog Includes Wire EDM Clamping Systems & Sets, Corner Sets, Ruler & Spanner, EDM Clamping Block, 3D Swivel Head, Vise Set, WEDM Vises and Magnetic Tables, Multiclamp, Wire EDM Pendulum Holder, V-Block, ICS Adapter, Beams, Beam IF, Z-Flex, Turn and Index Table, Collet Chuck Holder, EDM Link and Adapter, 3 Jaw Scroll Chuck ....etc. Workholding Tools Catalog - 1 Check this catalog for our 100% EROWA and 3R compatible workholding tools. We accept OEM work, you can send us a drawing for evaluation. Workholding Tools Catalog - 2 Check this catalog for our Workholding Devices, Die and Mold Clamps, Clamping Elements, Clamping Kits, Fixture Clamps, Toggle Clamps, Milling & MC Vices, Pneumatic & Hydraulic Clamps, Milling & Grinding Accessories, Wire Cut EDM Workholders...etc. We accept OEM work, you can send us a drawing for evaluation. You may also find our following page link useful: Industrial Machines and Equipment Manufacturing CLICK Product Finder-Locator Service RÛPERA BERÊ

AGS-TECH Inc. News and Announcements - Employment Opportunities - New Product Launch - Corporate News - News about Advancements in Manufacturing and Technology Nûçe û Daxuyan ji AGS-TECH Inc November 5 - 2021: AGS-TECH, Inc. has become a value added reseller of QualityLine production Technologies, Ltd., a high-tech company that has developed an Artificial Intelligence based software solution that automatically integrates with your worldwide manufacturing data and creates an advanced diagnostics analytics for you. This tool is really different than any others in the market, because it can be implemented very quickly and easily, and will work with any type of equipment and data, data in any format coming from your sensors, saved manufacturing data sources, test stations, manual entry .....etc. No need to change any of your existing equipment to implement this software tool. Besides real time monitoring of key performance parameters, this AI software provides you root cause analytics, provides early warnings and alerts. There is no solution like this in the market. This tool has saved manufacturers plenty of cash reducing rejects, returns, reworks, downtime and gaining customers goodwill. Easy and quick ! To schedule a Discovery Call with us and to find out more about this powerful artıficial intelligence based manufacturing analytics tool: - Please fill out the downloadable QL Questionnaire from the blue link on the left and return to us by email to sales@agstech.net . - Have a look at the blue colored downloadable brochure links to get an idea about this powerful tool. QualityLine One Page Summary and QualityLine Summary Brochure - Also here is a short video that gets to the point: VIDEO of QUALITYLINE MANUFACTURING AN ALYTICS TOOL September 18 - 2021: AGS-TECH, Inc. has become an ATOP Industrial-Networking and Computing Distribution Partner. You can now order ATOP industrial networking and switching products from us. We offer your enterprise both off-the-shelf as well as custom tailored solutions. Please check our webpages and download respective brochures to help you select the best solution. Download our ATOP TECHNOLOGIES compact product brochure (Download ATOP Technologies Product List 2021) February 4 - 2020: Due to the coronavirus outbreak, we would like to inform our customers that some of our production taking place in China will resume on the 10th of February due to government precautions and measures to stop the spreading. We are sorry for the delay caused by this unfortunate event. July 19 -2018: AGS-TECH, Inc. has launched its renewed global procurement website. Potential suppliers of products and services please visit our procurement & purchasing site http://www.agsoutsourcing.com We encourage you to fill out the online supplier application form by clicking here: https://www.agsoutsourcing.com/online-supplier-application-platfor Filling out this form will enable us to evaluate you as a potential supplier. This is the most preferred way of becoming a supplier of AGS-TECH, Inc., its branches and affiliates. Whether you are a custom manufacturer of parts ad components, an engineering integrator, engineering consultant or services provider, or anything else you may think would be beneficial to us, this is the form you should fill out. January 31 - 2018: AGS-TECH Inc. launched its new website. We hope our existing customers and new potential customers will enjoy our new website and frequently visit us online. January 23 - 2017: Our new Free Space Optical Components brochure is now available for download under Optical / Fiber Optic Products menu or directly from the following link - FREE SPACE OPTICAL COMPONENTS BROCHURE We hope you will find it easy to scroll through our new product brochure. April 27 - 2015: AGS-TECH Inc. has currently the following open positions available. More information about these openings can be obtained from Dr. Zach Miller. Interested applicants, please email your interest along with resumes to info@agstech.net (put as title Career Opportunities) - Project Coordinator (At least a B.S. in Engineering, Physics or Materials Science required. Ideal candidate must have in-depth knowledge and hands-on experience in CNC machining, aluminum die casting, metal forging, joining and assembly processes such as welding, soldering, brazing, fastening, quality control, test and measurement techniques used in metallurgy. At least 5 years industrial experience in US or Canada and fluency in English, Chinese, Mandarin is required. Must have US or Canadian citizenship. - Project Coordinator (At least a B.S. in Engineering, Physics or Materials Science required. Ideal candidate must have in-depth knowledge and experience on fiber optic passive components, DWDM, beamsplitters, optical fiber amplifiers, fiber optic components assembly, quality control, test and measurement techniques such as power monitoring, OTDR, splicing tools, spectrum analyzers used in fiber optics. At least 5 years industrial experience in US or Canada and fluency in English, Chinese, Mandarin is required. Must have US or Canadian citizenship. April 24 - 2015: AGS-TECH Inc. website is currently being updated. Please be patient in case some pages cannot be accessed or have problems. We apologize for the temporary inconvenience this may cause during your visit. March 2014: AGS-TECH Inc. has currently the following open positions available. More information about these openings can be obtained from Dr. Zach Miller. Interested applicants, please email your interest along with resumes to info@agstech.net (put as title Career Opportunities) - Project Coordinator (At least a B.S. in Engineering, Physics or Materials Science required. Ideal candidate must know about machining, casting, precision assembly, quality control, test and measurement techniques used in metallurgy. Fluency in English, Chinese, Mandarin and / or Vietnamese is required) - Project Coordinator (At least a B.S. in Engineering, Physics or Materials Science required. Ideal candidate must know about machining, casting, precision assembly, quality control, test and measurement techniques used in metallurgy. Must speak German and English fluently. Candidates stationed and living in Germany are preferred) - Senior Systems Engineer (At least a B.S. in Engineering, Physics or Materials Science required, at least 5 years industrial experience in fiber optic communication systems preferred, fluency in English, Chinese, Mandarin required) • November 2013: AGS-TECH Inc. is hiring. Interested applicants, please email your interest along with resumes to info@agstech.net Open positions exist for: - Senior Design Engineer (Wireless Communication Systems) - Senior Systems Engineer (Wireless Communication Systems) - Materials or Chemical Engineer (Nanofabrication) - Project Coordinator (must speak Chinese and English fluently) - Project Coordinator (must speak German and English fluently. Candidates stationed and living in Germany are preferred) RÛPERA BERÊ

Display - Touchscreen - Monitors - LED - OLED - LCD - PDP - HMD - VFD - ELD - SED - Flat Panel Displays - AGS-TECH Inc. Pêşandan & Touchscreen & Monitor Çêkirin û Civînê We offer: • Custom displays including LED, OLED, LCD, PDP, VFD, ELD, SED, HMD, Laser TV, flat panel display of required dimensions and electro-optic specifications. Please click on highlighted text to download relevant brochures for our display, touchscreen, and monitor products. - Catalog for Vandal-Proof IP65/IP67/IP68 Keyboards, Keypads, Pointing Devices, ATM Pinpads, Medical & Military Keyboards and other similar Rugged Computer Peripherals - Kiosk Systems (We private label these with your brand name and logo if you wish) - Kiosk Systems Accessories Guide (We private label these with your brand name and logo if you wish) - LED display panels - LCD modules - Mobile Computers for Enterprises (We private label these with your brand name and logo if you wish) - Process Automation Solutions (This brochure includes some industrial display products. We private label these with your brand name and logo if you wish) Download our brochure for TRu Multi-Touch Monitors. This monitor product line consists of a range of desktop, open frame, slim line and large format multi-touch displays - from 15” to 70''. Built for quality, responsiveness, visual appeal, and durability, TRu Multi-Touch Monitors complement any multi-touch interactive solution. Click here for pricing If you would like to have LCD modules specially designed & manufactured according to your requirements, please fill out and email us: Custom design form for LCD modules If you would like to have LCD panels specially designed & manufactured according to your requirements, please fill out and email us: Custom design form for LCD panels • Custom touchscreen ( such as iPod ) • Among the custom products our engineers have developed are: - A contrast measuring station for liquid crystal displays. - A computerized centering station for television projection lenses Panels / Displays are electronic screens used to view data and / or graphics and are available in a variety of sizes and technologies. Here are the meanings of abbreviated terms related to display, touchscreen and monitor devices: LED: Light Emitting Diode LCD: Liquid Crystal Display PDP: Plasma Display Panel VFD: Vacuum Fluorescent Display OLED: Organic Light Emitting Diode ELD: Electroluminescent Display SED: Surface-conduction Electron-emitter Display HMD: Head Mounted Display A significant benefit of OLED display over liquid crystal display (LCD) is that OLED does not require a backlight to function. Therefore OLED display draws far less power and, when powered from a battery, can operate longer as compared to LCD. Because there is no need for a backlight, an OLED display can be much thinner than an LCD panel. However, degradation of OLED materials has limited their use as display, touchscreen and monitor. ELD works by exciting atoms by passing an electric current through them, and causing ELD to emit photons. By varying the material being excited, the colour of the emitted light can be changed. ELD is constructed using flat, opaque electrode strips running parallel to each other, covered by a layer of electroluminescent material, followed by another layer of electrodes, running perpendicular to the bottom layer. The top layer must be transparent in order to let light go through and escape. At each intersection, the material lights, thereby creating a pixel. ELDs are sometimes used as backlights in LCDs. They are also useful for creating soft ambient light, and for low-colour, high-contrast screens. A surface-conduction electron-emitter display (SED) is a flat panel display technology that uses surface conduction electron emitters for each individual display pixel. The surface conduction emitter emits electrons that excite a phosphor coating on the display panel, similar to cathode ray tube (CRT) televisions. In other words, SEDs use tiny cathode ray tubes behind every single pixel instead of one tube for the whole display, and can combine the slim form factor of LCDs and plasma displays with the superior viewing angles, contrast, black levels, color definition and pixel response time of CRTs. It is also widely claimed that SEDs consume less power than LCD displays. A head-mounted display or Helmet mounted display, both abbreviated 'HMD', is a display device, worn on the head or as part of a helmet, that has a small display optic in front of one or each eye. A typical HMD has either one or two small displays with lenses and semi-transparent mirrors embedded in a helmet, eye-glasses or visor. The display units are small and may include CRT, LCDs, Liquid Crystal on Silicon, or OLED. Sometimes multiple micro-displays are deployed to increase total resolution and field of view. HMDs differ in whether they can display just a computer generated image (CGI), show live images from the real world or a combination of both. Most HMDs display only a computer-generated image, sometimes referred to as a virtual image. Some HMDs allow superimposing a CGI upon a real-world view. This is sometimes referred to as augmented reality or mixed reality. Combining real-world view with CGI can be done by projecting the CGI through a partially reflective mirror and viewing the real world directly. For partially reflective mirrors, check our page on Passive Optical Components. This method is often called Optical See-Through. Combining real-world view with CGI can also be done electronically by accepting video from a camera and mixing it electronically with CGI. This method is often called Video See-Through. Major HMD applications include military, governmental (fire, police, etc.) and civilian/commercial (medicine, video gaming, sports, etc.). Military, police and firefighters use HMDs to display tactical information such as maps or thermal imaging data while viewing the real scene. HMDs are integrated into the cockpits of modern helicopters and fighter aircraft. They are fully integrated with the pilot's flying helmet and may include protective visors, night vision devices and displays of other symbols and information. Engineers and scientists use HMDs to provide stereoscopic views of CAD (Computer Aided Design) schematics. These systems are also used in the maintenance of complex systems, as they can give a technician an effectively ''x-ray vision'' by combining computer graphics such as system diagrams and imagery with the technician's natural vision. There are also applications in surgery, wherein a combination of radiographic data (CAT scans and MRI imaging) is combined with the surgeon's natural view of the operation. Examples of lower cost HMD devices can be seen with 3D games and entertainment applications. Such systems allow 'virtual' opponents to peek from real windows as a player moves about. Other interesting developments in display, touchscreen and monitor technologies AGS-TECH is interested are: Laser TV: Laser illumination technology remained too costly to be used in commercially viable consumer products and too poor in performance to replace lamps except in some rare ultra-high-end projectors. More recently however, companies demonstrated their laser illumination source for projection displays and a prototype rear-projection ''laser TV''. The first commercial Laser TV and subsequently others have been unveiled. First audiences who were shown reference clips from popular movies reported that they were blown away by a Laser TV's hitherto unseen color-display prowess. Some people even describe it as being too intense to the point of seeming artificial. Some other future display technologies will likely include carbon nanotubes and nanocrystal displays using quantum dots to make vibrant and flexible screens. As always, if you provide us details of your requirement and application, we can design and custom manufacture displays, touchscreens and monitors for you. Click here to download brochure of our Panel Meters - OICASCHINT Dowload brochure for our DESIGN PARTNERSHIP PROGRAM More information on our engineering work can be found on: http://www.ags-engineering.com CLICK Product Finder-Locator Service RÛPERA BERÊ

Surface Treatment and Modification - Surface Engineering - Hardening - Plasma - Laser - Ion Implantation - Electron Beam Processing at AGS-TECH Tedawiyên Rûyê û Guhertin Surfaces cover everything. The appeal and functions material surfaces provide us are of utmost importance. Therefore SURFACE TREATMENT and SURFACE MODIFICATION are among our everyday industrial operations. Surface treatment & modification leads to enhanced surface properties and can be performed either as a final finishing operation or prior to a coating or joining operation. The processes of surface treatments and modification (also referred to as SURFACE ENGINEERING), tailor the surfaces of materials and products to: - Control friction and wear - Improve corrosion resistance - Enhance adhesion of subsequent coatings or joined parts - Change physical properties conductivity, resistivity, surface energy and reflection - Change chemical properties of surfaces by introducing functional groups - Change dimensions - Change the appearance, e.g., color, roughness…etc. - Clean and / or disinfect the surfaces Using surface treatment and modification, the functions and service lives of materials can be improved. Our common surface treatment and modification methods can be divided into two major categories: Surface Treatment and Modification That Covers Surfaces: Organic Coatings: The organic coatings apply paints, cements, laminates, fused powders and lubricants on the surfaces of materials. Inorganic Coatings: Our popular inorganic coatings are electroplating, autocatalytic plating (electroless platings), conversion coatings, thermal sprays, hot dipping, hardfacing, furnace fusing, thin film coatings such as SiO2, SiN on metal, glass, ceramics,….etc. Surface treatment and modification involving coatings is explained in detail under the related submenu, please click here Functional Coatings / Decorative Coatings / Thin Film / Thick Film Surface Treatment and Modification That Alters Surfaces: Here on this page we will concentrate on these. Not all of the surface treatment and modification techniques we describe below are on the micro or nano-scale, but we will nevertheless mention about them briefly since the basic objectives and methods are similar to significant extent to those that are on the micromanufacturing scale. Hardening: Selective surface hardening by laser, flame, induction and electron beam. High Energy Treatments: Some of our high energy treatments include ion implantation, laser glazing & fusion, and electron beam treatment. Thin Diffusion Treatments: Thin diffusion processes include ferritic-nitrocarburizing, boronizing, other high temperature reaction processes such as TiC, VC. Heavy Diffusion Treatments: Our heavy diffusion processes include carburizing, nitriding, and carbonitriding. Special Surface Treatments: Special treatments such as cryogenic, magnetic, and sonic treatments affect both the surfaces and the bulk materials. The selective hardening processes can be carried out by flame, induction, electron beam, laser beam. Large substrates are deep hardened using flame hardening. Induction hardening on the other hand is used for small parts. Laser and electron beam hardening are sometimes not distinguished from those in hardfacings or high-energy treatments. These surface treatment and modification processes are applicable only to steels that have sufficient carbon and alloy content to allow quench hardening. Cast irons, carbon steels, tool steels, and alloy steels are suitable for this surface treatment and modification method. Dimensions of parts are not significantly altered by these hardening surface treatments. Depth of hardening can vary from 250 microns to the whole section depth. However, in the whole section case, the section must be thin, less than 25 mm (1 in), or small, since the hardening processes require a rapid cooling of materials, sometimes within a second. This is difficult to achieve in large workpieces, and therefore in large sections, only the surfaces can be hardened. As a popular surface treatment and modification process we harden springs, knife blades, and surgical blades among many other products. High-energy processes are relatively new surface treatment and modification methods. Properties of surfaces are changed without changing the dimensions. Our popular high-energy surface treatment processes are electron beam treatment, ion implantation, and laser beam treatment. Electron Beam Treatment: Electron beam surface treatment alters the surface properties by rapid heating and rapid cooling — in the order of 10Exp6 Centigrade/sec (10exp6 Fahrenheit/sec) in a very shallow region around 100 microns near the material surface. Electron beam treatment can also be used in hardfacing to produce surface alloys. Ion Implantation: This surface treatment and modification method uses electron beam or plasma to convert gas atoms to ions with sufficient energy, and implant/insert the ions into atomic lattice of the substrate, accelerated by magnetic coils in a vacuum chamber. Vacuum makes it easier for ions to move freely in the chamber. The mismatch between implanted ions and the surface of the metal creates atomic defects that hardens the surface. Laser Beam Treatment: Like the electron beam surface treatment and modification, laser beam treatment alters the surface properties by rapid heating and rapid cooling in a very shallow region near the surface. This surface treatment & modification method can also be used in hardfacing to produce surface alloys. A know-how in Implant dosages and treatment parameters makes it possible for us to use these high energy surface treatment techniques in our fabrication plants. Thin Diffusion Surface Treatments: Ferritic nitrocarburizing is a case hardening process that diffuses nitrogen and carbon into ferrous metals at sub-critical temperatures. The processing temperature is usually at 565 Centigrade (1049 Fahrenheit). At this temperature steels and other ferrous alloys are still in a ferritic phase, which is advantageous compared to other case hardening processes that occur in the austenitic phase. The process is used to improve: •scuffing resistance •fatigue properties •corrosion resistance Very little shape distortion occurs during the hardening process thanks to the low processing temperatures. Boronizing, is the process where boron is introduced to a metal or alloy. It is a surface hardening and modification process by which boron atoms are diffused into the surface of a metal component. As a result the surface contains metal borides, such as iron borides and nickel borides. In their pure state these borides have extremely high hardness and wear resistance. Boronized metal parts are extremely wear resistant and will often last up to five times longer than components treated with conventional heat treatments such as hardening, carburizing, nitriding, nitrocarburizing or induction hardening. Heavy Diffusion Surface Treatment and Modification: If the carbon content is low (less than 0.25% for example) then we can increase the carbon content of the surface for hardening. The part can be either heat-treated by quenching in a liquid or cooled in still air depending on the properties desired. This method will only allow local hardening on the surface, but not in the core. This is sometimes very desirable because it allows for a hard surface with good wear properties as in gears, but has a tough inner core that will perform well under impact loading. In one of the surface treatment and modification techniques, namely Carburizing we add carbon to the surface. We expose the part to a Carbon rich atmosphere at an elevated temperature and allow diffusion to transfer the Carbon atoms into the steel. Diffusion will happen only if the steel has low carbon content, because diffusion works on the differential of the concentrations principle. Pack Carburizing: Parts are packed in a high carbon medium such as carbon powder and heated in a furnace for 12 to 72 hours at 900 Centigrade (1652 Fahrenheit). At these temperatures CO gas is produced which is a strong reducing agent. The reduction reaction occurs on the surface of the steel releasing carbon. The carbon is then diffused into the surface thanks to the high temperature. The Carbon on the surface is 0.7% to 1.2% depending on process conditions. The hardness achieved is 60 - 65 RC. The depth of the carburized case ranges from about 0.1 mm up to 1.5 mm. Pack carburizing requires good control of temperature uniformity and consistency in heating. Gas Carburizing: In this variant of surface treatment, Carbon Monoxide (CO) gas is supplied to a heated furnace and the reduction reaction of deposition of carbon takes place on the surface of the parts. This process overcomes most of the problems of pack carburizing. One concern however is the safe containment of the CO gas. Liquid Carburizing: The steel parts are immersed in a molten carbon rich bath. Nitriding is a surface treatment and modification process involving diffusion of Nitrogen into the surface of steel. Nitrogen forms Nitrides with elements such as Aluminum, Chromium, and Molybdenum. The parts are heat-treated and tempered before nitriding. The parts are then cleaned and heated in a furnace in an atmosphere of dissociated Ammonia (containing N and H) for 10 to 40 hours at 500-625 Centigrade (932 - 1157 Fahrenheit). Nitrogen diffuses into the steel and forms nitride alloys. This penetrates to a depth of up to 0.65 mm. The case is very hard and distortion is low. Since the case is thin, surface grinding is not recommended and therefore nitriding surface treatment may not be an option for surfaces with very smooth finishing requirements. Carbonitriding surface treatment and modification process is most suitable for low carbon alloy steels. In the carbonitriding process, both Carbon and Nitrogen are diffused into the surface. The parts are heated in an atmosphere of a hydrocarbon (such as methane or propane) mixed with Ammonia (NH3). Simply put, the process is a mix of Carburizing and Nitriding. Carbonitriding surface treatment is performed at temperatures of 760 - 870 Centigrade (1400 - 1598 Fahrenheit), It is then quenched in a natural gas (Oxygen free) atmosphere. The carbonitriding process is not suitable for high precision parts due to the distortions that are inherent. The hardness achieved is similar to carburizing (60 - 65 RC) but not as high as Nitriding (70 RC). The case depth is between 0.1 and 0.75 mm. The case is rich in Nitrides as well as Martensite. Subsequent tempering is needed to reduce brittleness. Special surface treatment and modification processes are in the early stages of development and their effectiveness is as yet unproven. They are: Cryogenic Treatment: Generally applied on hardened steels, slowly cool down the substrate to about -166 Centigrade (-300 Fahrenheit) to increase the density of the material and thus increase the wear resistance and dimension stability. Vibration Treatment: These intend to relieve thermal stress built-up in heat treatments through vibrations and increase the wear life. Magnetic Treatment: These intend to alter the line-up of atoms in materials through magnetic fields and hopefully improve the wear life. The effectiveness of these special surface treatment and modification techniques still remains to be proven. Also these three techniques above affect the bulk material besides surfaces. Please download our catalogs and brochures by clicking on the blue colored text below: - Private Label Nano Surface Protection Car Care Products We can label these products with your name and logo if you wish - Private Label Nano Surface Protection Industrial Products We can label these products with your name and logo if you wish - Private Label Nano Surface Protection Marine Products We can label these products with your name and logo if you wish - Private Label Nano Surface Protection Products We can label these products with your name and logo if you wish CLICK Product Finder-Locator Service RÛPERA BERÊ

Sheet Metal Forming and Fabrication, Stamping, Punching, Bending, Progressive Die, Spot Welding, Deep Drawing, Metal Blanking and Slitting at AGS-TECH Inc. Stampings & Sheet Metal Fabrication We offer sheet metal stamping, shaping, forming, bending, punching, blanking, slitting, perforating, notching, nibbling, shaving, pressworking, fabrication, deep drawing using single punch / single stroke dies as well as progressive dies and spinning, rubber forming and hydroforming; sheet metal cutting using water jet, plasma, laser, saw, flame; sheet metal assembly using welding, spot welding; sheet metal tube bulging and bending; sheet metal surface finishing including dip or spray painting, electrostatic powder coating, anodizing, plating, sputtering and more. Our services range from rapid sheet metal prototyping to high volume manufacturing. We recommend that you click here to DOWNLOAD our Schematic Illustrations of Sheet Metal Fabrication and Stamping Processes by AGS-TECH Inc. This will help you better understand the information we are providing you below. • SHEET METAL CUTTING : We offer CUTOFFS and PARTINGS. Cutoffs cut the sheet metal over one path at a time and there is basically no waste of material, whereas with partings the shape cannot be nestled precisely and therefore certain amount of material is wasted. One of our most popular processes is PUNCHING, where a piece of material round or other shape is cut out from sheet metal. The piece that is cut out is waste. Another version of punching is SLOTTING, where rectangular or elongated holes are punched. BLANKING on the other hand is the same process as punching, with the distinction of the piece being cut out is the work and is kept. FINE BLANKING, a superior version of blanking, creates cuts with close tolerances and straight smooth edges and does not require secondary operations for perfection of the workpiece. Another process we frequently use is SLITTING, which is a shearing process where sheet metal is cut by two opposing circular blades in a straight or curved path. Can opener is a simple example of the slitting process. Another popular process for us is PERFORATING, where many holes round or other shape are punched in sheet metal in a certain pattern. A typical example for a perforated product is metal filters with many holes for fluids. In NOTCHING, another sheet metal cutting process, we remove material from a work piece, starting at the edge or elsewhere and cut inward until the desired shape is obtained. It is a progressive process where each operation removes another piece until the desired contour is obtained. For small production runs we sometimes use a relatively slower process called NIBBLING which consists of many rapid punches of overlapping holes to make a larger more complex cut. In PROGRESSIVE CUTTING we use a series of different operations to obtain a single cut or a certain geometry. Finally SHAVING a secondary process helps us to improve edges of cuts that have already been made. It is used for cutting off the chips, rough edges on sheet metal work. • SHEET METAL BENDING : Besides cutting, bending is an essential process without which we would not be able to produce most products. Mostly a cold working operation but sometimes also performed when warm or hot. We use dies and press most of the time for this operation. In PROGRESSIVE BENDING we use a series of different punch and die operations to obtain a single bend or a certain geometry. AGS-TECH uses a variety of bending processes and makes the choice depending on the workpiece material, its size, thickness, desired size of bend, radius, curvature and angle of bend, location of bend, economy of operation, quantities to be manufactured…etc. We use V-BENDING where a V shaped punch forces the sheet metal into the V shaped die and bends it. Good for both very acute and obtuse angles and in between, including 90 degrees. Using wiping dies we perform EDGE BENDING. Our equipment enables us to obtain angles even larger than 90 degrees. In edge bending the workpiece is sandwiched between a pressure pad and the die, the area for bending is located on the die edge and the rest of the workpiece is held over space like a cantilever beam. When the punch acts on the cantilever portion, it is bent over the edge of the die. FLANGING is an edge bending process resulting in a 90 degree angle. Main goals of the operation are the elimination of sharp edges and obtaining geometric surfaces to ease the joining of parts. BEADING, another common edge bending process forms a curl over a part’s edge. HEMMING on the other hand results with an edge of the sheet that is bent completely over on itself. In SEAMING, the edges of two parts are bent over on each other and joined. DOUBLE SEAMING on the other hand provides watertight and airtight sheet metal joints. Similar to edge bending, a process called ROTARY BENDING deploys a cylinder with the desired angle cut out and serving as the punch. As the force is transmitted to the punch, it closes with the workpiece. The groove of the cylinder gives the cantilever portion the desired angle. The groove can have an angle smaller or larger than 90 degrees. In AIR BENDING, we do not need the lower die to have an angled groove. The sheet metal is supported by two surfaces on opposite sides and at a certain distance. The punch then applies a force at the right location and bends the workpiece. CHANNEL BENDING is performed using a channel shaped punch and die, and U-BEND is achieved with a U-shaped punch. OFFSET BENDING produces offsets on the sheet metal. ROLL BENDING, a technique good for thick work and bending of large pieces of metal plates, uses three rolls to feed and bend the plates to desired curvatures. Rolls are arranged so that the desired bend of the work is obtained. The distance and angle between the rolls is controlled to obtain the desired outcome. A moveable roll makes it possible to control the curvature. TUBE FORMING is another popular sheet metal bending operation involving multiple dies. Tubes are obtained after multiple actions. CORRUGATION is also performed by bending operations. Basically it is the symmetrical bending at regular intervals across an entire piece of sheet metal. Various shapes can be used for corrugating. Corrugated sheet metal is more rigid and has better resistance against bending and therefore has applications in the construction industry. SHEET METAL ROLL FORMING, a continuous manufacturing process is deployed to bend cross sections of a certain geometry using rolls and the work is bent in sequential steps, with the final roll completing the work. In some cases a single roll and in some cases a series of rolls are employed. • COMBINED SHEET METAL CUTTING & BENDING PROCESSES : These are the processes that cut and bend at the same time. In PIERCING, a hole is createdusing a pointed punch. As the punchwidens the hole in the sheet, the material is bent simultaneously into an internal flange for the hole. The flange obtained may have important functions. The LANCING operation on the other hand cuts and bends the sheet to create a raised geometry. • METAL TUBE BULGING AND BENDING : In BULGING some internal part of a hollow tube is pressurized, causing the tube to bulge outward. Since the tube is inside a die, the bulge geometry is controlled by the shape of the die. In STRETCH BENDING, a metal tube is stretched using forces parallel to the tube’s axis and bending forces to pull the tube over a form block. In DRAW BENDING, we clamp the tube near its end to a rotating form block that bends the tube while rotating. Lastly, in COMPRESSION BENDING the tube is held by force to a fixed form block, and a die bends it over the form block. • DEEP DRAWING : In one of our most popular operations, a punch, a matching die and a blank holder are used. The sheet metal blank is placed over the die opening and the punch moves towards the blank held by the blank holder. Once they come into contact, the punch forces the sheet metal into the die cavity to form the product. Deep drawing operation resembles cutting, however the clearance between the punch and die prevents the sheet from being cut. Another factor assuring the sheet is deep drawn and not cut are the rounded corners on the die and punch which prevents the shearing and cutting. To achieve a greater magnitude of deep drawing, a REDRAWING process is being deployed where a subsequent deep drawing takes place on a part that has already undergone a deep drawing process. In REVERSE REDRAWING, the deep drawn part is flipped over and drawn in the opposite direction. Deep drawing can provide irregular shaped objects such as domed, tapered or stepped cups, In EMBOSSING we use a male and female die pair to impress the sheet metal with a design or script. • SPINNING : An operation where a flat or preformed workpiece is held between a rotating mandrel and tail stock and a tool applies localized pressure to the work as it gradually moves up the mandrel. As a result, the workpiece is wrapped over the mandrel and takes its shape. We use this technique as an alternative to deep drawing where the quantity of an order is small, the parts are large (diameters up to 20 feet) and have unique curves. Even though the per piece prices are generally higher, the set-up costs for CNC spinning operation are low compared to deep drawing. To the contrary, deep drawing requires high initial investment for set-up, but the per piece costs are low when high quantity of parts are produced. Another version of this process is SHEAR SPINNING, where there is also metal flow within the workpiece. The metal flow will reduce the thickness of the workpiece as the process is carried out. Yet another related process is TUBE SPINNING, which is applied on cylindirical parts. Also in this process there is metal flow within the workpiece. The thickness is thus reduced and the tube’s length is increased. The tool can be moved to create features on the inside or outside of the tube. • RUBBER FORMING OF SHEET METAL : Rubber or polyurethane material is put in a container die and the work piece is placed on the surface of the rubber. A punch is then acted upon the work piece and forces it into the rubber. Since the pressure generated by the rubber is low, the depth of parts produced is limited. Since tooling costs are low, the process is suitable for low quantity production. • HYDROFORMING : Similar to rubber forming, in this process sheet metal work is pressed by a punch into a pressurized liquid inside a chamber. The sheet metal work is sandwiched between the punch and a rubber diaphragm. The diaphragm surrounds the workpiece completely and the pressure of the fluid forces it to form on the punch. Very deep draws even deeper than in the deep drawing process can be obtained with this technique. We manufacture single-punch dies as well as progessive dies depending on your part. Single stroke stamping dies are a cost effective method for producing large quantities of simple sheet metal parts such as washers quickly. Progressive dies or the deep drawing technique are used for manufacturing more complex geometries. Depending on your case, waterjet, laser or plasma cutting can be used to produce your sheet metal parts inexpensively, fast and accurately. Many suppliers have no idea about these alternative techniques or do not have it and therefore they go through lengthy and expensive ways of making dies and tools that only waste customers time and money. If you require custom built sheet metal components such as enclosures, electronic housings...etc as fast as within days, then contact us for our RAPID SHEET METAL PROTOTYPING service. CLICK Product Finder-Locator Service MENU BERÊ

Plastic and Rubber Parts, Mold Making, Injection Molding, Thermoforming, Blow Mould, Vacuum Forming, Thermoset Mold, Polymer Components, at AGS-TECH Inc. Qalibên Plastîk & Gomûk û Molding We custom manufacture plastic and rubber moulds and moulded parts using injection moulding, transfer molding, thermoforming, compression moulding, thermoset moulding, vacuum forming, blow moulding, rotational moulding, insert moulding, pour moulding, metal to rubber and metal to plastic bonding, ultrasonic welding, secondary manufacturing & fabrication processes. We recommend that you click here to DOWNLOAD our Schematic Illustrations of Plastic and Rubber Molding Processes by AGS-TECH Inc. This will help you better understand the information we are providing you below. • INJECTION MOULDING : A thermoset compound is fed and injected with a high speed reciprocating screw or plunger system. Injection molding can produce small to medium sized parts in high volume economically, tight tolerances, consistency between parts and good strength can be achieved. This technique is the most common plastic products manufacturing method of AGS-TECH Inc. Our standard moulds have cycle times in the order of 500,000 times and are made of P20 tool steel. With larger injection moulds and deeper cavities consistency and hardness throughout the material becomes even more important, therefore we only use certified highest quality tool steel from major suppliers with strong traceability and quality assurance systems. Not all P20 tool steels are the same. Their quality can vary from supplier to supplier and from country to country. Therefore for even our injection moulds manufactured in China we use tool steel imported from US, Germany and Japan. We have accumulated the know-how of using modified P20 steel chemistries for injection moulding of products with surfaces requiring very tight tolerance mirror finishes. This makes us capable of manufacturing even optical lens moulds. Another type of challenging surface finish is textured surfaces. These necessitate consistent hardness across the surface. Therefore any inhomogeneity in the steel can result in less than perfect surface textures. For this reason some of our steel used for such moulds incorporates special alloying elements and is cast using advanced metallurgical techniques. Miniature plastic parts and gears are components that require know how on suitable plastic materials and processes which we have gained over the years. We manufacture tiny precision plastic components with tight tolerances for a company making micromotors. Not every plastic moulding company is capable of producing such tiny accurate parts, because it requires know-how which is acquired only through years of research and development experience. We offer the various types of this molding technique, including gas assisted injection molding. • INSERT MOULDING : Inserts can either be incorporated at the time of the molding process, or be inserted after the molding process. When incorporated as part of the molding process, the inserts can be loaded by robots or by the operator. If the inserts are incorporated after the molding operation, they can usually be applied any time after the molding process. A common insert moulding process is the process of molding plastic around preformed metal inserts. For example, electronic connectors do have metal pins or components enclosed by the sealing plastic material. We have acquired years of experience keeping the cycle time constant from shot to shot even in post moulding insertion, because variations in cycle time between shots will result in poor quality. • THERMOSET MOLDING : This technique is characterized by the requirement of heating the mold versus cooling for thermoplastic. Parts manufactured by thermoset molding are ideal for applications requiring high mechanical strength, widely usable temperature range and unique dielectric properties. Thermosetting plastics can be molded in any of the three molding processes: Compression, Injection or Transfer molding. The delivery method of the material into the mold cavities distinguishes these three techniques. For all three processes, a mold constructed of mild or hardened tool steel is heated. The mold is chrome plated to reduce wear on the mold and improve part release. Parts are ejected with hydraulically actuated ejector pins and air poppets. Part removal can either be manual or automatic. Thermoset moulded components for electrical applications require stability against flow and melt at elevated temperatures. As everyone knows, electrical and electronic components warm up during operation and only suitable plastic materials can be used for safety and long term operation. We are experienced in CE and UL qualifications of plastic components for the electronic industry. • TRANSFER MOLDING : A measured amount of molding material is preheated and inserted into a chamber known as the transfer pot. A mechanism known as the plunger forces the material from the pot through the channels known as sprue and runner system into mold cavities. While material is inserted the mold remains closed and is only opened when it is time to release the produced part. Keeping the mold walls at a higher than melting temperature of the plastic material assures fast flow of material through the cavities. We use this technique for frequently for: - Encapsulation purposes where complex metallic inserts are molded into the part - Small to medium sized parts at reasonably high volume - When parts with tight tolerances are needed and low shrinkage materials are necessary - Consistency is needed because the transfer molding technique allows consistent material delivery • THERMOFORMING : This is a generic term used to describe a group of processes to produce plastic parts from flat sheets of plastic under temperature and pressure. In this technique plastic sheets are heated and formed over a male or female mold. After forming they are trimmed to create a usable product. The trimmed material is reground and recycled. Basically there are two types of thermoforming processes, namely vacuum forming and pressure forming (which are explained below). Engineering and tooling costs are low and turnaround times are short. Therefore this method is well suited for prototyping and low volume production. Some thermoform plastic materials are ABS, HIPS, HDPE, HMWPE, PP, PVC, PMMA, modified PETG. The process is suitable for large panels, enclosures and housings and is preferable for such products to injection molding due to lower cost and faster tooling manufacture. Thermoforming is best suited for parts with important features mostly confined to one of its sides. However, AGS-TECH Inc. is capable to use the technique together with additional methods such as trimming, fabrication and assembly to manufacture parts that have critical features on both sides. • COMPRESSION MOULDING : Compression molding is a forming process where a plastic material is placed directly into a heated metal mold, where it is softened by the heat and forced to conform to the shape of the mold as the mold closes. Ejector pins in the bottom of the molds quickly eject finished pieces from the mold and the process is finished. Thermoset plastic in either preform or granular pieces is commonly used as the material. Also high-strength fiberglass reinforcements are suitable for this technique. To avoid excess flash, the material is measured prior to molding. The advantages of compression molding are its ability to mold large intricate parts, being one of the lowest cost molding methods compared with other methods such as injection moulding; little material waste. On the other hand, compression molding often provides poor product consistency and relatively difficult control of flash. When compared to injection molding, there are fewer knit lines produced and a smaller amount of fiber length degradation occurs. Compression-molding is also suitable for ultra-large basic shape production in sizes beyond the capacity of extrusion techniques. AGS-TECH uses this technique to manufacture mostly electrical parts, electrical housings, plastic cases, containers, knobs, handles, gears, relatively large flat and moderately curved parts. We possess the know-how of determining the right amount of raw material for cost efficient operation and reduced flash, adjusting to the right amount of energy and time for heating the material, choosing the most suitable heating technique for each project, calculating the required force for optimal shaping of material, optimized mould design for fast cooling after each compression cycle. • VACUUM FORMING (also described as a simplified version of THERMOFORMING) : A plastic sheet is heated until soft and draped over a mold. Vacuum is then applied and the sheet is being sucked into the mold. After the sheet takes the desired shape of the mould, it is cooled off and ejected from the mold. AGS-TECH uses sophisticated pneumatic, heat and hydrolic control to achieve high speeds in production by vacuum forming. Materials suitable for this technique are extruded thermoplastic sheets such as ABS, PETG, PS, PC, PVC, PP, PMMA, acrylic. The method is most suitable for forming plastic parts that are rather shallow in depth. However we also manufacture relatively deep parts by mechanically or pneumatically stretching the formable sheet prior to bringing it into contact with the mold surface and applying vacuum. Typical products molded by this technique are foot trays & containers, enclosures, sandwich boxes, shower trays, plastic pots, automobile dashboards. Because the technique uses low pressures, inexpensive mold materials can be used and molds can be manufactured in short time inexpensively. Low quantity production of large parts is thus a possibility. Depending on quantity of production mould functionality can be enhanced when high volume production is needed. We are professional in determining what quality of mold each project requires. It would be a waste of customer’s money and resources to manufacture an unnecessarily complex mold for a low volume production run. For example products such as enclosures for large sized medical machines for production quantities in the range of 300 to 3000 units/year can be vacuum formed from heavy gauge raw materials instead of manufactured with expensive techniques such as injection moulding or sheet metal forming. • BLOW MOULDING : We use this technique for producing hollow plastic parts (also glass parts). A preform or parison which is a tube-like plastic piece is clamped into a mould and compressed air is blown into it through the hole in one end. As a result the plastic perform / parison is pushed outward and acquires the shape of the mould cavity. After the plastic is cooled and solidified, it is ejected from the mould cavity. There are three types of this technique: -Extrusion blow moulding -Injection blow moulding -Injection stretch blow moulding Common materials used in these processes are PP, PE, PET, PVC. Typical items produced using this technique are plastic bottles, buckets, containers. • ROTATIONAL MOULDING (also called ROTAMOULDING or ROTOMOULDING) is a technique suitable to produce hollow plastic products. In rotational molding heating, melting, shaping and cooling occur after the polymer is put into the mold. No external pressure is applied. Rotamolding is economical for producing large products, mold costs are low, products are stress free, no polymer weld lines, few design constraints to deal with. The rotomolding process begins with charging the mold, in other words a controlled amount of polymer powder is put in the mould, closed and loaded into oven. Inside the oven the second process step is carried out: Heating and Fusion. The mould is rotated around two axes with relatively low speed, heating takes place and the molten polymer powder melts and sticks to the mould walls. Thereafter the third step, the cooling takes place solidifying the polymer inside the mould. Lastly, the unloading step involves opening of the mould and removal of the product. These four process steps are then repeated again and again. Some materials used in rotomoulding are LDPE, PP, EVA, PVC. Typical products produced are large plastic products such as SPA, childrens playground slides, large toys, large containers, rainwater tanks, traffic cones, canoes and kayaks...etc. Since rotationally moulded products are generally of large geometries and costly to ship, an important point to remember in rotational moulding is to consider designs that facilitate stacking of products into each other prior to shipment. We help our clients during their design phase if required. • POUR MOLDING : This method is used when multiple items need to be produced. A hollowed out block is used as a mold and filled by simply pouring the liquid material such as melted thermoplastic or a mixture of resin and hardener into it. By doing this one either produces the parts or another mold. The liquid such as plastic is then left to harden and takes on the shape of the mold cavity. Release agent materials are commonly used to release parts from the mold. Pour molding is also sometimes referred to as Plastic Potting or Urethane Casting. We use this process for inexpensively manufacturing products in the shape of statues, ornaments….etc., products that do not need excellent uniformity or excellent material properties but rather only the shape of an object. We sometimes make silicon molds for prototyping purposes. Some of our low volume projects are processed using this technique. Pour moulding can be used for manufacturing glass, metal and ceramic parts as well. Since the set-up and tooling costs are minimal, we consider this technique whenever low quantity production of multiple items with minimal tolerance requirements is on the table. For high volume production, the pour molding technique is generally not suitable because it is slow and therefore expensive when large quantities need to be manufactured. There are however exceptions where pour moulding can be used for large quantity production, such as pour molding potting compounds to encapsulate electronic and electrical components and assemblies for insulation and protection. • RUBBER MOLDING – CASTING – FABRICATION SERVICES : We custom manufacture rubber components from natural as well as synthetic rubber using some of the above explained processes. We can adjust the hardness and other mechanical properties according to your application. By incorporating other organic or inorganic additives, we can increase the heat stability of your rubber parts such as balls for high temperature cleaning purposes. Various other properties of rubber can be modified as needed and desired. Also be assured that we do not use toxic or hazardous materials for manufacturing toys or other elastomer / elastomeric molded products. We provide Material Safety Data Sheets (MSDS), conformance reports, material certifications and other documents such as ROHS compliance for our materials and products. Additional special tests are carried out at certified government or government approved laboratories if needed. We have been manufacturing automobile mats from rubber, small rubber statues and toys for many years. • SECONDARY MANUFACTURING & FABRICATION PROCESSES : Finally, keep in mind that we also offer a large variety of secondary processes such as chrome coating of plastic products for mirror-type applications or giving plastics the metal-like shiny finish. Ultrasonic welding is another example of a secondary process offered for plastic components. Yet a third example of secondary process on plastics can be surface treatment prior to coating to enhance coating adhesion. Automobile bumpers are well known to benefit from this secondary process. Metal-rubber bonding, metal-plastic bonding are other common processes we are experienced with. When we evaluate your project, we can jointly determine which secondary processes would be the most suitable for your product. Here are some of commonly used plastic products. Since these are off-the-shelf, you can save on mould costs in case any of these fits your requirements. Click here to download our economic 17 Series Hand Held Plastic Enclosures from AGS-Electronics Click here to download our 10 Series Sealed Plastic Enclosures from AGS-Electronics Click here to download our 08 Series Plastic Cases from AGS-Electronics Click here to download our 18 Series Special Plastic Enclosures from AGS-Electronics Click here to download our 24 Series DIN Plastic Enclosures from AGS-Electronics Click here to download our 37 Series Plastic Equipment Cases from AGS-Electronics Click here to download our 15 Series Modular Plastic Enclosures from AGS-Electronics Click here to download our 14 Series PLC Enclosures from AGS-Electronics Click here to download our 31 Series Potting and Power Supply Enclosures from AGS-Electronics Click here to download our 20 Series Wall-Mounting Enclosures from AGS-Electronics Click here to download our 03 Series Plastic and Steel Enclosures from AGS-Electronics Click here to download our 02 Series Plastic and Aluminum Instrument Case Systems II from AGS-Electronics Click here to download our 16 Series DIN rail module enclosures from AGS-Electronics Click here to download our 19 Series Desktop Enclosures from AGS-Electronics Click here to download our 21 Series Card Reader Enclosures from AGS-Electronics CLICK Product Finder-Locator Service VEGEHA MENÛYA BERÊ

AGS-TECH, Inc. Company Information - Manufacturing - Fabrication - Assembly - Moulding - Casting - CNC Machining - Extrusion - Forging - Electrical & Electronic AGS-TECH, Inc. ya we ye Çêkerê Xweseriya Gloverî, Integrator, Hevkar, Hevkarê Derveyî. Em ji bo çêkirin, çêkirin, endezyarî, hevgirtin, derxistina derve çavkaniya weya yek-rawest in. Agahdariya Pargîdaniyê - Çêkirin & Çêkirin & Civîn li AGS-TECH Inc Hûn bi xêr hatin AGS-TECH Inc.! Em di peydakirina cûrbecûr hilber û karûbarên pîşesaziyê de pêşengek cîhanî ya damezrandî ne. Cûdahiya me ev e ku em dikanek yek rawestgehê ne ku hûn dikarin piraniya hewcedariyên xwe yên PÊŞKIRIN, ÇÊKIRIN û MAVKIRINA KIRIN, MÛÇE, PLASTÎK Û ÇÛÇIK, ÇÊKIRINA MERÎ, ÇÊBÛNA Û ÇÊKIRINA METALE, ÇÊKIRINA METAL, ÇÊKIRIN, ÇÊKIRIN, MECHINING, POWDER METALLURJI, ELEMÊN MAKÎNE, Çêkirina SERAMÎKÊN TEKNÎK, ELECTRONIKÊN CUSTOM, OPTÎK, kombûna FIBER OPTÎK, AMAMÊN TEST û METROLOJIYÊ, KOMPÛTERÊN PÊŞEsaziyê, KOMPYÊRÊN PÊŞEsaziyê, ELECTRONIKÊN XWEZAYÊN û her weha bidestxistina xizmetên piştgirî û karsaziyê. Ne hewce ye ku hûn ji gelek deveran bikirin da ku hûn hemî beş û pêkhateyên hilber û projeyên xwe bikirin, hûn ne hewce ne ku bi her dabînkerê re ji hev cuda mijûl bibin, hilberan bişînin paş û paş… hwd. Ev pir dijwar û biha ye. Me ew hemî ji bo we li yek cîhek heye! Em dikarin ji bo we hemîyan yek bikin ku hûn lêçûnên hilberandin, çêkirin, civandin, pakkirin, nîşankirin û barkirinê kêm bikin. Em dikarin sêwiran bikin, çêkin, bicivînin, biqedînin, pak bikin, etîket bikin, depo bikin û wan ji we re an xerîdarên we re bişînin. Ger barkêşkerek we tune be, em dikarin ji we re karê barkêş, import û gumrikê bikin. Ger hûn bixwazin em dikarin bi nav û logoya we re bişînin. Ji ber ku em gerdûnî dixebitin, em dikarin ji we re peyda bikin 1.) Qalîteya çêtir 2.) Bihayên çêtir 3.) Demên Pêşkêşiya Baştir. Hêza me ji tîmê meya elît tê ku ji rêberên xwenda, xwedî ezmûn û damezrandî yên ku li cîhên me yên gerdûnî yên stratejîk bicîh bûne pêk tê. Koma teknolojiya pêşkeftî ya me bi sedan endezyarên gerdûnî yên naskirî û rêveberên teknîkî yên demsalî yên li DY, li YE û Asyaya Başûr-rojhilatê torgilokek heye. Endamên tîmê meya teknîkî ya pêşkeftî di warên pisporiya xwe de gelek patentan digirin, gelekan xwedan bi dehan weşanên di kovarên naskirî yên navneteweyî de ne û dahêner in ku ji zanîngehên bilind ên Cîhanê dersên mezûniyetê ne. Em bi berdewamî pêşkeftinên herî dawî yên teknolojiyê dişopînin da ku cîhê xwe wekî rêber bihêlin. Tîmên me li DY û YE û her weha li welatên kêm lêçûn ên wekî Chinaîn, Hindistan, Taywan, Hong Kong, Koreya Başûr hene ku beşek girîng a hilberên me têne çêkirin. Bazirganiya me û navenda firotanê li Dewletên Yekbûyî yên Amerîkayê ye. Dema ku Daîreya meya QC (Kontrola Kalîteyê) ji nêz ve hemî daneyên çêkirin û barkirinê dişopîne, meylên bikêrhatî, berberî, vegerandin, ji nû ve xebitandin û rêjeyên hilweşandinê li her kargehê analîz dike û li ser başkirina domdar dixebite, tîmê meya kirrûbirrê bi berdewamî li meylên karsazî û teknolojîk dinihêre. hilber û derfetên nû da ku em her gav çêtirîn çêtirîn pêşkêşî xerîdarên xwe bikin. Parastina milkê rewşenbîrî ya xerîdarên me ji bo me pir girîng e û ji ber vê yekê em tenê li ser bingeha "Pêdivî ye ku bizanibin" di nav rêxistina xwe de agahdarî radigihînin. Ofîsên me yên deryayî rojane bi tîmê meya bingehîn re li Dewletên Yekbûyî ji nêz ve dixebitin ji ber vê yekê em hemî ji bo heman armancê ne: Ji bo ku xerîdarên me di sûka gerdûnî de biserkevin û pêşbaztir bibin. Xerîdarên me çiqasî serketî û pêşbaz bin, em ê ewqasî bi ser bikevin. Ger hûn xerîdarek heyî ne, ji kerema xwe gelek caran li malpera me bigerin da ku nûvekirinên hilberên nû yên ku em dişînin her ku hebe bibînin. Heke hûn ji me re nû ne, ji kerema xwe di malpera me de biçin da ku hûn pargîdaniya me çêtir fam bikin û yek ji nexşeyên xwe yên teknîkî, nexşe, pelên taybetmendiyê, nimûneyan ji me re bişînin û ji destê pêşîn bihayên pêşbaziyê yên ku em dikarin pêşkêşî bikin bibînin. Me ji bo piraniya xerîdarên xwe lêçûnên kirînê ji% 50 an zêdetir kêm kiriye. Çima li Cîhanek ku tenê pargîdaniyên herî pêşbaz dikarin bijîn zêdetir bidin? Aqilmend bin û nehêlin kesên din bi hincetên bêaqil we bi bihayên bêaqil bidin we, mîna peydakirina çêkirin û çêkirina kalîteya bilind tenê ji bo buhayên bilind, an jî bi îddîayên pêkenok ên wekî Hem-Amerîkî ne dema ku ew 90% ji parçeyên xwe îthal dikin. û tenê wan ji nû ve nîşan bikin ... hwd. Van peyvan hemî ji me re bêaqil in, ji ber ku em baş dizanin ku kalîteya hêja û radest dikare ji bo perçeyek bihayê were pêşkêş kirin! Referansên xerîdar ji me bipirsin û em ê kêfxweş bibin ku wan ji we re peyda bikin. Li gorî hewcedariyên we em dikarin hilberên we li hundur an deryavî hilberînin. Em pir baş dizanin kengê hilberîna navmalî maqûltir e û kengê der-dor maqûltir e. Heke hûn bi piranî li şûna kapasîteyên çêkirin, çêkirin û berhevkirinê bi kapasîteyên me yên endezyar û lêkolîn û pêşkeftinê re eleqedar in, wê hingê em we vedixwînin ku hûn biçin malpera meya endezyariyê http://www.ags-engineering.com Read More Mîsyona Meya Hilberîna Raborî û Niha Read More Nûçe & Daxuyaniyên ji AGS-TECH, Inc. Read More Ji bo Entegratorê Endezyariyê û Hilberînerê Xweserî Bibin Dabînker AGS-TECH Inc. Read More Cûdahiya AGS-TECH: Çêkera Xwerû ya Herî Cûda ya Cîhanê, Hevkar, Integratorê Endezyariyê û Hevkarê Derveyî Read More Otomasyon / Piçûk-Batch û Hilberîna Komkujî li AGS-TECH Inc Read More Hilberîna Yekgirtî ya Komputerê li AGS-TECH Inc Read More Rêvebiriya Kalîteyê li AGS-TECH Inc Read More Em çawa Projeyan Dibêjin? Hêman, Meclîs û Berhemên Xweser ên Hilberînerî Dibêjin Read More Lojîstîk & Barkirin & Depokirin & Barkirina Tenê-Di-Wextê de li AGS-TECH Inc. Read More Mercên Firotanê yên Giştî li AGS-TECH Inc Read More Çavkaniyên Mişterî Em AGS-TECH Inc., çavkaniya weya yek-stop ji bo çêkirin û çêkirin û endezyarî û jêderxistin û yekbûnek we ne. Em entegratora endezyariya herî cihêreng a Cîhanê ne ku hilberîna xwerû, binecivîn, komkirina hilberan û karûbarên endezyariyê pêşkêşî we dikin.