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Mechanical Seals, Induction Cap Sealing, Adhesive Sealant, Bung - Diaphragm Ferrofluidic Seal, Flange Gasket, O-Ring - Piston Ring, Hydrostatic, Labyrint Seal Производство на механички заптивки A MECHANICAL SEAL is a device which helps join systems or mechanisms together by preventing leakage, containing pressure, or excluding contamination. Mechanical seals can vary in their construction from a simple-O-Ring to complicated assembled structures containing lubricants inside labyrinth shaped canals and self-aligning functionality. Many types of mechanical seals are available. Some of our mechanical seals are available from stock and can be ordered by catalog part number, and on the other hand custom manufacturing option of mechanical seals is available for our customers. So we can design and manufacture mechanical seals specially for your application. The effectiveness of a seal is dependent on adhesion in the case of sealants and compression in the case of gaskets. Major MECHANICAL SEAL TYPES we offer are: Induction sealing or cap sealing, Adhesive sealant, Bridgman seal, a piston sealing mechanism that creates a high pressure reservoir from a lower pressure source, Bung, Coating, Compression seal fitting, Diaphragm seal, Ferrofluidic seal, Gasket or Mechanical Packing, Flange gasket, O-ring, V-ring, U-cup, Wedge, Bellows, D-ring, Delta rings, T-rings, Lobed ring, O-ring boss seal, Piston ring, Glass-ceramic-to-metal seals, Hose coupling, various types of hose couplings, Hermetic seal, Hydrostatic seal, Hydrodynamic seal, Labyrinth seal, a seal which creates a tortuous path for the liquid to flow through, Lid (container), Rotating face mechanical seal, Face seal, Plug, Radial shaft seal, Trap (siphon trap), Stuffing Box, Gland Assembly (mechanical packing), Split Mechanical Seal, Wiper seal, Dry gas seal, Exitex seal, Radial seal, Felt radial seal, Radial positive-contact seals, Clearance seals, Split-ring seal, Axial mechanical seal, End face seals, Molded packings, Lip-type and squeeze type packing, Static seals and sealants, Flat nonmetallic gaskets, Metallic gaskets, Exclusion seals (wiper, scraper, axial and boot seals) Our stocked mechanical seals include famous brands including Timken, AGS-TECH as well as other quality brands. Below you can click and download catalogues of some of the most popular seals. Please tell us the catalogue number/model number and the quantity you would like to order and we will offer you the best prices and lead times along with offers for alternative brands similar in quality. We can supply original brand name as well as generic brand name mechanical seals. TIMKEN SEALS: - Download Timken Large Bore Industrial Seal Catalog Small Bore Bonded Seal Catalog - NSC Info Section NSC Manufacturers NSC Numeric & Metric NSC Numerical Lists NSC Oil Seals 410027- 9Y9895 NSC O Rings Oil Seals up to 410005 NSC Size Section MATERIALS USED IN MECHANICAL SEALS: All our mechanical seals are assembled from the finest materials. The type of lubricant and the mean operating temperature generally govern the choice of elastomer to be used for the mechanical seal compound. Nitrile rubber compounds are among the most widely used sealing materials because temperatures seldom exceed 220 F (105 C). Nitrile rubber has good wear characteristics, easy to mold and inexpensive sealing materials used in seals. For some seals special oil resistant silicone compounds are preferred. For high end applications fluoroelastomer compounds such as Viton are used in seals because they have a long life at very high temperatures in almost any lubricant. Seals incorporating fluoroelastomers are higher in cost however. At low temperatures fluoroelastomers get stiff but not brittle. КЛИКНЕТЕ Услуга за пронаоѓање на производи-локатор ПРЕТХОДНА СТРАНИЦА

Custom Manufactured Parts, Assemblies, Plastic Mold, Rubber Molding, Metal Casting, CNC Machining, Turning, Milling, Electrical Electronic Optical Assembly PCBA Прилагодено произведени делови и склопови и производи Прочитај повеќе Пластични и гумени калапи и калапи Прочитај повеќе Лиење и обработка Прочитај повеќе Екструзии, екструдирани производи Прочитај повеќе Печатење и изработка на лим Прочитај повеќе Метално ковање и металургија во прав Прочитај повеќе Формирање на жица и пружини Прочитај повеќе Формирање и обликување на стакло и керамика Прочитај повеќе Адитив и брзо производство Прочитај повеќе Производство на композити и композитни материјали Прочитај повеќе Процеси на спојување и склопување и прицврстување 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. ПРЕТХОДНА СТРАНИЦА

Optical Displays, Screen, Monitors, Touch Panel Manufacturing Производство и склопување на оптички дисплеи, екрани, монитори Преземете ја брошурата за нашата ПРОГРАМА ЗА ПАРТНЕРСТВО ЗА ДИЗАЈН КЛИКНЕТЕ Услуга за пронаоѓање на производи-локатор ПРЕТХОДНА СТРАНИЦА

Test Equipment, Hardness Tester, Digital Multimeter, Metallurgical Microscope, Thickness Gauge, Vibration Meter, Ultrasonic Flaw Detectors, Vibration Meters Индустриска опрема за тестирање Прочитај повеќе Тестери за цврстина Прочитај повеќе Thickness and Flaw Gauges & Detectors Прочитај повеќе Инструменти за тестирање на површината за обложување Прочитај повеќе Мерачи за вибрации, тахометри Прочитај повеќе Микроскоп, фиберскоп, борескоп, машини за мерење на видот, проектори за профили Прочитај повеќе Инструменти за тестирање на оптички влакна Read More Инструменти за механички испитувања Read More Термичка и IR тест опрема Прочитај повеќе Хемиски, физички, еколошки анализатори Прочитај повеќе Електрична и електронска опрема за тестирање Прочитај повеќе Специјализирана опрема за тестирање за тестирање на производи КЛИКНЕТЕ Услуга за пронаоѓање на производи-локатор Продаваме неколку видови на индустриска опрема од врвни брендови како Hartip-SADT, Wiggenhauser, Fluke, Mitech, Hewlet-Packard, Oxford Instruments, Olympus... итн.: • Опрема за проверка и тестирање на материјали • Опрема за обработка и тестирање на хемикалии • Опрема за инспекција и тестирање на електронски производи • Опрема за тестирање на еколошки параметри • Опрема за тестирање на оптички параметри • Опрема за мерење на магнетни својства • Метролошка опрема за градежната индустрија • Автомобилска опрема за тестирање и инспекција • Телекомуникациска опрема за тестирање • Опрема за медицинска и биолошка метрологија AGS-TECH Inc. нуди напредна опрема за пристапни цени. Нудиме најкорисна, разноврсна, доверлива и прифатлива опрема од познати брендови. Продаваме опрема што ги исполнува признатите индустриски стандарди како што се CE и UL. Нашата опрема нуди уникатни предности кои ќе ги намалат трошоците за производство, тестирање и контрола на квалитетот. Иако продажбата на нашата опрема е за сосема нови производи, одвреме-навреме можеме да ви понудиме обновени или користени по намалени цени. Преземете ја брошурата за нашата ПРОГРАМА ЗА ПАРТНЕРСТВО ЗА ДИЗАЈН Ако некој од нашите производи изгледа интересен или имате прашања, ве молиме јавете ни се на +1-505-5506501 или ни е-пошта на sales@agstech.net Често проверувајте ја нашата веб-страница, бидејќи како што станува достапна опрема, ние објавуваме некои од нив на оваа страница, а мнозинството на http://www.sourceindustrialsupply.com ПРЕТХОДНА СТРАНИЦА

How to Become a Supplier for Engineering Integrator and Custom Manufacturer AGS-TECH Inc. of Albuquerque - NM - USA Станете добавувач за инженерски интегратор и прилагоден производител AGS-TECH Inc. Want to become a global supplier for engineering integrator and custom manufacturer AGS-TECH Inc. ? To become a potential supplier for us: 1.) Please click here to visit our supplier platform: https://www.agsoutsourcing.com/online-supplier-application-platfor 2.) On this form, please fill out as much detail as possible. Once your data is entered into our system it is filtered, screened and evaluated. Depending on keywords and input content, it is categorized, rated and evaluated for further processing. If your company is found appropriate and suitable for our needs, we will then send you RFQs (Request for Quote) and RFPs (Request for Proposal). Since we are a custom manufacturer and engineering integrator, of particular value to us are global manufacturers in areas where the most shortage of skill is present. If you are a supplier for the following, we encourage you to register your company to our database via the above link: -Custom manufacturer of low to medium volume plastic moulds (100 to 500 pieces per order). -Custom manufacturer of low to medium volume metal castings and CNC machined parts (100 to 500 pieces per order). -Engineering integrator and custom manufacturer that has the capability to be a supplier of both metal and polymer parts and that can accept parts assembly as part of a contract. -Small to intermediate volume custom manufacturer of electric cable assemblies and wire harness (100 to 500 pieces per order). -Engineering integrator with capability to integrate custom hardware with new software. -Supplier of test and metrology equipment that is new to us and not to be found in our brochures. -Engineering integrator and custom manufacturer who can complement or contribute to our product lines in unique ways. -Engineering integrator and custom manufacturer of micromanufactured and mesomanufactured products such as miniature custom sensors and actuators, miniature electronic and optoelectronic devices. -Supplier of smaller quantity custom coatings. As an engineering integrator and custom manufacturer we bring together parts, subassemblies and products from the best plants and assemble them together, package and label them according to requirements and ship to our customers. Integration is the process of bringing together the components into one system and ensuring that the subsystems function together as a system. To keep our spot as a distinguished engineering integrator and custom manufacturer, we have to keep working with the finest suppliers and assure that they do have valid and up-to-date quality related certifications obtained from well established certification bodies. An ISO9001, TS16949, QS9000, AS9001, ISO13485 are among the first requirements for any custom manufacturer of products and/or provider of engineering services to us. In addition to one of these certifications, any custom manufacturer or engineering services provider will need to present further evidence of being capable to contribute successfully to our engineering and integration efforts by showing examples of products for which a CE or UL mark was obtained, evidence of having successfully sold products meeting international standards such as IEEE, IEC, ASTM, DIN, MIL-SPEC…etc. to customers in the US, Canadian, Australian, EU and Japanese markets. If you are an engineering integrator and custom manufacturer, you are especially important for us because of your ability to integrate at least some of the components at your facility before shipping them to us. Being a globally recognized engineering integrator and custom manufacturer, logistics is a key element in our business. We must keep being able to ship fast, damage-free and economically. Therefore having presence in one of the logistically key locations is very important for every engineering integrator and custom manufacturer willing to collaborate and partner with us. Logistics is a complex issue we constantly work on and keep improving. As an example, sometimes the best option is to ship a product as individual components and parts from one or several plants to an assembly plant that is in the vicinity of our customer. This saves on shipping cost because the final product may be large and bulky and the final assembly plant being close to customer will keep shipping prices to a minimum and at the same time be a safer option where the most value is put into the product that is shipped only a short distance to its final destination. ПРЕТХОДНА СТРАНИЦА

Micromanufacturing - Surface & Bulk Micromachining - Microscale Manufacturing - MEMS - Accelerometers - AGS-TECH Inc. Микропроизводство / Микропроизводство / Микромашина / MEMS MICROMANUFACTURING, MICROSCALE MANUFACTURING, MICROFABRICATION or MICROMACHINING refers to our processes suitable for making tiny devices and products in the micron or microns of dimensions. Sometimes the overall dimensions of a micromanufactured product may be larger, but we still use this term to refer to the principles and processes that are involved. We use the micromanufacturing approach to make the following types of devices: Microelectronic Devices: Typical examples are semiconductor chips that function based on electrical & electronic principles. Micromechanical Devices: These are products that are purely mechanical in nature such as very small gears and hinges. Microelectromechanical Devices: We use micromanufacturing techniques to combine mechanical, electrical and electronic elements at very small length scales. Most of our sensors are in this category. Microelectromechanical Systems (MEMS): These microelectromechanical devices also incorporate an integrated electrical system in one product. Our popular commercial products in this category are MEMS accelerometers, air-bag sensors and digital micromirror devices. Depending on the product to be fabricated, we deploy one of the following major micromanufacturing methods: BULK MICROMACHINING: This is a relatively older method which uses orientation-dependent etches on single-crystal silicon. The bulk micromachining approach is based on etching down into a surface, and stopping on certain crystal faces, doped regions, and etchable films to form the required structure. Typical products we are capable of micromanufacturing using bulk micromachining technique are: - Tiny cantilevers - V-groves in silicon for alignment and fixation of optical fibers. SURFACE MICROMACHINING: Unfortunately bulk micromachining is restricted to single-crystal materials, since polycrystalline materials will not machine at different rates in different directions using wet etchants. Therefore surface micromachining stands out as an alternative to bulk micromachining. A spacer or sacrificial layer such as phosphosilicate glass is deposited using CVD process onto a silicon substrate. Generally speaking, structural thin film layers of polysilicon, metal, metal alloys, dielectrics are deposited onto the spacer layer. Using dry etching techniques, the structural thin film layers are patterned and wet etching is used to remove the sacrificial layer, thereby resulting in free-standing structures such as cantilevers. Also possible is using combinations of bulk and surface micromachining techniques for turning some designs into products. Typical products suitable for micromanufacturing using a combination of the above two techniques: - Submilimetric size microlamps (in the order of 0.1 mm size) - Pressure sensors - Micropumps - Micromotors - Actuators - Micro-fluid-flow devices Sometimes, in order to obtain high vertical structures, micromanufacturing is performed on large flat structures horizontally and then the structures are rotated or folded into an upright position using techniques such as centrifuging or microassembly with probes. Yet very tall structures can be obtained in single crystal silicon using silicon fusion bonding and deep reactive ion etching. Deep Reactive Ion Etching (DRIE) micromanufacturing process is carried out on two separate wafers, then aligned and fusion bonded to produce very tall structures that would otherwise be impossible. LIGA MICROMANUFACTURING PROCESSES: The LIGA process combines X-ray lithography, electrodeposition, molding and generally involves the following steps: 1. A few hundreds of microns thick polymethylmetacrylate (PMMA) resist layer is deposited onto the primary substrate. 2. The PMMA is developed using collimated X-rays. 3. Metal is electrodeposited onto the primary substrate. 4. PMMA is stripped and a freestanding metal structure remains. 5. We use the remaining metal structure as a mould and perform injection molding of plastics. If you analyze the basic five steps above, using the LIGA micromanufacturing / micromachining techniques we can obtain: - Freestanding metal structures - Injection molded plastic structures - Using injection molded structure as a blank we can investment cast metal parts or slip-cast ceramic parts. The LIGA micromanufacturing / micromachining processes are time consuming and expensive. However LIGA micromachining produces these submicron precision molds which can be used to replicate the desired structures with distinct advantages. LIGA micromanufacturing can be used for example to fabricate very strong miniature magnets from rare-earth powders. The rare-earth powders are mixed with an epoxy binder and pressed to the PMMA mold, cured under high pressure, magnetized under strong magnetic fields and finally the PMMA is dissolved leaving behind the tiny strong rare-earth magnets which are one of the wonders of micromanufacturing / micromachining. We are also capable to develop multilevel MEMS micromanufacturing / micromachining techniques through wafer-scale diffusion bonding. Basically we can have overhanging geometries within MEMS devices, using a batch diffusion bonding and release procedure. For example we prepare two PMMA patterned and electroformed layers with the PMMA subsequently released. Next, the wafers are aligned face to face with guide pins and press fit together in a hot press. The sacrificial layer on one of the substrates is etched away which results in one of the layers bonded to the other. Other non-LIGA based micromanufacturing techniques are also available to us for the fabrication of various complex multilayer structures. SOLID FREEFORM MICROFABRICATION PROCESSES: Additive micromanufacturing is used for rapid prototyping. Complex 3D structures can be obtained by this micromachining method and no material removal takes place. Microstereolithography process uses liquid thermosetting polymers, photoinitiator and a highly focused laser source to a diameter as small as 1 micron and layer thicknesses of about 10 microns. This micromanufacturing technique is however limited to production of nonconducting polymer structures. Another micromanufacturing method, namely “instant masking” or also known as “electrochemical fabrication” or EFAB involves the production of an elastomeric mask using photolithography. The mask is then pressed against the substrate in an electrodeposition bath so that the elastomer conforms to substrate and excludes plating solution in contact areas. Areas that are not masked are electrodeposited as the mirror image of the mask. Using a sacrificial filler, complex 3D shapes are microfabricated. This “instant masking” micromanufacturing / micromachining method makes it also possible to produce overhangs, arches…etc. КЛИКНЕТЕ Услуга за пронаоѓање на производи-локатор ПРЕТХОДНА СТРАНИЦА

Global Product Finder & Product Locator Service, AI based productor finding, AI based product locating AGS-TECH, Inc. е ваш Глобален прилагоден производител, интегратор, консолидатор, аутсорсинг партнер. Ние сме вашиот едношалтерски извор за производство, изработка, инженерство, консолидација, аутсорсинг. Глобална услуга за пронаоѓање и локатор на производи Нашата услуга за пронаоѓање производи / локатор на производи е обезбедена во обид брзо да го лоцираме производот што го барате. Ја користиме нашата одобрена база на податоци за глобални добавувачи, како и нашите сопствени софтверски алатки за вештачка интелигенција (ВИ) за брзо лоцирање на производот што го барате. Нашата услуга за пронаоѓање производи / локатор на производи гарантира дека добивате понуда брзо и со најдобра достапна цена. Едноставно обидете се да видите како функционира: КЛИКНИ ТУКА Кликнете овде ако точно го знаете производот што го барате КЛИКНИ ТУКА Кликнете овде ако делумно го знаете производот што го пребарувате КЛИКНИ ТУКА Кликнете овде ако ви треба производ направен по нарачка Ние сме AGS-TECH Inc., ваш единствен извор за производство и изработка и инженерство и аутсорсинг и консолидација. Ние сме најразновидниот инженерски интегратор во светот кој ви нуди сопствено производство, подсклопување, склопување на производи и инженерски услуги.

AGS-TECH Inc. supplies off-the-shelf as well as custom manufactured brushes. Many types are offered including industrial brush, agricultural brushes, municipal brushes, copper wire brush, zig zag brush, roller brush, side brushes, metal polishing brush, window cleaning brushes, heavy industrial scrubbing brush...etc. Четки и четки Производство AGS-TECH has experts in the consultancy, design and manufacturing of brushes for cleaning and processing equipment manufacturers. We work with you to offer innovative custom brush design solutions. Brush prototypes are developed before volume production runs. We help you to design, develop and manufacture high quality brushes for optimal machine performance. Products can be produced almost at any dimensional specifications you prefer or is suitable for your application. Also the brush bristles can be of various lengths and materials. Both natural and synthetic bristles and materials are being used in our brushes depending on the application. Sometimes we are able to offer you an off-the-shelf brush that will fit your application and needs. Just let us know your needs and we are here to help you. Some of the types of brushes we are able to supply you are: Industrial Brushes Agricultural Brushes Vegetable Brushes Municipal Brushes Copper Wire Brush Zig Zag Brushes Roller Brush Side Brushes Roller Brushes Disk Brushes Circular Brushes Ring Brushes and Spacers Cleaning Brushes Conveyor Cleaning Brush Polishing Brushes Metal Polishing Brush Window Cleaning Brushes Glass Manufacturing Brushes Trommel Screen Brushes Strip Brushes Industrial Cylinder Brushes Brushes with Varying Bristle Lengths Variable & Adjustable Bristle Length Brushes Synthetic Fibers Brush Natural Fibers Brush Lath Brush Heavy Industrial Scrubbing Brushes Specialist Commercial Brushes If you do have detailed blueprints of brushes you need manufactured, that is perfect. Just send them to us for evaluation. If you do not have blueprints, no problem. A sample, a photo or a hand sketch of the brush may be sufficient initially for most projects. We will send you special templates to fill in your requirements and details so we can evaluate, design and manufacture your product correctly. In our templates we have questions on details such as: Brush face length Tube length Tube inside and outside diameters Disk inside and outside diameters Disk thickness Brush diameter Brush height Tuft diameter Density Material and color of bristles Bristle diameter Brush pattern & fill pattern (double row helical, double row chevron, full fill,….etc.) Brush drive of choice Applications for the brushes (food, pharmaceuticals, polishing of metals, industrial cleaning…etc.) With your brushes we can supply you accessories such as pad holders, hooked pads, necessary attachments, disk drives, drive coupling…etc. If you are unfamiliar with these brush specs, again no problem. We will guide you throughout the design process. PREVIOUS PAGE

Electric Discharge Machining - EDM - Spark Machining - Die Sinking - Wire Erosion - Custom Manufacturing - AGS-TECH Inc. EDM обработка, глодање и мелење со електрично празнење ELECTRICAL DISCHARGE MACHINING (EDM), also referred to as SPARK-EROSION or ELECTRODISCHARGE MACHINING, SPARK ERODING, DIE SINKING or WIRE EROSION, is a NON-CONVENTIONAL MANUFACTURING process where erosion of metals takes place and desired shape is obtained using electrical discharges in the form of sparks. We also offer some varieties of EDM, namely NO-WEAR EDM, WIRE EDM (WEDM), EDM GRINDING (EDG), DIE-SINKING EDM, ELECTRICAL-DISCHARGE MILLING, micro-EDM, m-EDM and ELECTROCHEMICAL-DISCHARGE GRINDING (ECDG). Our EDM systems consist of shaped tools/electrode and the workpiece connected to DC power supplies and inserted in a electrically nonconducting dielectric fluid. After 1940 electrical discharge machining has become one of the most important and popular production technologies in manufacturing industries. When the distance between the two electrodes is reduced, the intensity of the electric field in the volume between the electrodes becomes greater than the strength of the dielectric in some points, which breaks, eventually forming a bridge for current to flow between the two electrodes. An intense electrical arc is generated causing significant heating to melt a portion of the workpiece and some of the tooling material. As a result, material is removed from both the electrodes. At the same time, the dielectric fluid is heated rapidly, resulting in evaporation of the fluid in the arc gap. Once the current flow stops or it is stopped heat is removed from the gas bubble by the surrounding dielectric fluid and the bubble cavitates (collapses). The shock wave created by the bubble’s collapse and the flow of dielectric fluid flush debris from the workpiece surface and entrain any molten workpiece material into the dielectric fluid. The repetition rate for these discharges are between 50 to 500 kHz, voltages between 50 to 380 V and currents between 0.1 and 500 Amperes. New liquid dielectric such as mineral oils, kerosene or distilled & deionized water is usually conveyed into the inter-electrode volume carrying away the solid particles (in the form of debris) and the insulating proprieties of the dielectric is restored. After a current flow, the potential difference between the two electrodes is restored to what it was before the breakdown, so a new liquid dielectric breakdown can occur. Our modern electrical discharge machines (EDM) offer numerically controlled movements and are equipped with pumps and filtering systems for the dielectric fluids. Electrical discharge machining (EDM) is a machining method mainly used for hard metals or those that would be very difficult to machine with conventional techniques. EDM typically works with any materials that are electrical conductors, although methods for machining insulating ceramics with EDM have also been proposed. The melting point and latent heat of melting are properties that determine the volume of metal removed per discharge. The higher these values, the slower the material removal rate. Because the electrical discharge machining process does not involve any mechanical energy, the hardness, strength, and toughness of the workpiece do not affect the removal rate. Discharge frequency or energy per discharge, the voltage and current are varied to control material removal rates. Rate of material removal and surface roughness increase with increasing current density and decreasing spark frequency. We can cut intricate contours or cavities in pre-hardened steel using EDM without the need for heat treatment to soften and re-harden them. We can use this method with any metal or metal alloys like titanium, hastelloy, kovar, and inconel. Applications of the EDM process include shaping of polycrystalline diamond tools. EDM is considered a non-traditional or non-conventional machining method along with processes such as electrochemical machining (ECM), water jet cutting (WJ, AWJ), laser cutting. On the other hand the conventional machining methods include turning, milling, grinding, drilling and other process whose material removal mechanism is essentially based on mechanical forces. Electrodes for electrical-discharge machining (EDM) are made of graphite, brass, copper and copper-tungsten alloy. Electrode diameters down to 0.1mm are possible. Since tool wear is an undesired phenomenon adversely affecting dimensional accuracy in EDM, we take advantage of a process called NO-WEAR EDM, by reversing polarity and using copper tools to minimize tool wear. Ideally speaking, the electrical-discharge machining (EDM) can be considered a series of breakdown and restoration of the dielectric liquid between the electrodes. In reality however, the removal of the debris from the inter-electrode area is almost always partial. This causes the electrical proprieties of the dielectric in the inter-electrodes area to be different from their nominal values and vary with time. The inter-electrode distance, (spark-gap), is adjusted by the control algorithms of the specific machine used. The spark-gap in EDM can unfortunately sometimes be short-circuited by the debris. The control system of the electrode may fail to react quickly enough to prevent the two electrodes (tool and workpiece) from short circuiting. This unwanted short circuit contributes to material removal differently from the ideal case. We pay utmost importance to flushing action in order to restore the insulating properties of the dielectric so that the current always happens in the point of the inter-electrode area, thereby minimizing the possibility of unwanted change of shape (damage) of the tool-electrode and workpiece. To obtain a specific geometry, the EDM tool is guided along the desired path very close to the workpiece without touching it, We pay utmost attention to the performance of motion control in use. This way, a large number of current discharges / sparks take place, and each contributes to the removal of material from both tool and workpiece, where small craters are formed. The size of the craters is a function of the technological parameters set for the specific job at hand and dimensions may range from the nanoscale (such as in the case of micro-EDM operations) to some hundreds of micrometers in roughing conditions. These small craters on the tool cause gradual erosion of the electrode called “tool wear”. To counteract the detrimental effect of the wear on the geometry of the workpiece we continuously replace the tool-electrode during a machining operation. Sometimes we achieve this by using a continuously replaced wire as electrode ( this EDM process is also called WIRE EDM ). Sometimes we use the tool-electrode in such a way that only a small portion of it is actually engaged in the machining process and this portion is changed on a regular basis. This is, for instance, the case when using a rotating disk as a tool-electrode. This process is called EDM GRINDING. Yet another technique we deploy consists of using a set of electrodes with different sizes and shapes during the same EDM operation to compensate for wear. We call this multiple electrode technique, and is most commonly used when the tool electrode replicates in negative the desired shape and is advanced towards the blank along a single direction, usually the vertical direction (i.e. z-axis). This resembles the sink of the tool into the dielectric liquid in which the workpiece is immersed, and therefore it is referred to as DIE-SINKING EDM (sometimes called CONVENTIONAL EDM or RAM EDM). The machines for this operation are called SINKER EDM. The electrodes for this type of EDM have complex forms. If the final geometry is obtained using a usually simple-shaped electrode moved along several directions and is also subject to rotations, we call it EDM MILLING. The amount of wear is strictly dependent on the technological parameters used in the operation ( polarity, maximum current, open circuit voltage). For example, in micro-EDM, also known as m-EDM, these parameters are usually set at values which generates severe wear. Therefore, wear is a major problem in that area which we minimize using our accumulated know-how. For example to minimize wear to graphite electrodes, a digital generator, controllable within milliseconds, reverses polarity as electro-erosion takes place. This results in an effect similar to electroplating that continuously deposits the eroded graphite back on the electrode. In another method, a so-called ''Zero Wear'' circuit we minimize how often the discharge starts and stops, keeping it on for as long a time as possible. The material removal rate in electrical-discharge machining can be estimated from: MRR = 4 x 10 exp(4) x I x Tw exp (-1.23) Here MRR is in mm3/min, I is current in Amperes, Tw is workpiece melting point in K-273.15K. The exp stands for exponent. On the other hand, the wear rate Wt of the electrode can be obtained from: Wt = ( 1.1 x 10exp(11) ) x I x Ttexp(-2.38) Here Wt is in mm3/min and Tt is melting point of the electrode material in K-273.15K Finally, the wear ratio of the workpiece to electrode R can be obtained from: R = 2.25 x Trexp(-2.38) Here Tr is the ratio of melting points of workpiece to electrode. SINKER EDM : Sinker EDM, also referred to as CAVITY TYPE EDM or VOLUME EDM, consists of an electrode and workpiece submerged in an insulating liquid. The electrode and workpiece are connected to a power supply. The power supply generates an electrical potential between the two. As the electrode approaches the workpiece, dielectric breakdown occurs in the fluid, forming a plasma channel, and a small spark jumps. The sparks usually strike one at a time because it is highly unlikely that different locations in the inter-electrode space have identical local electrical characteristics which would enable a spark to occur in all such locations simultaneously. Hundreds of thousands of these sparks happen at random points between the electrode and the workpiece per second. As the base metal erodes, and the spark gap subsequently increases, the electrode is lowered automatically by our CNC machine so that the process can continue uninterrupted. Our equipment has controlling cycles known as ''on time'' and ''off time''. The on time setting determines the length or duration of the spark. A longer on time produces a deeper cavity for that spark and all subsequent sparks for that cycle, creating a rougher finish on the workpiece and vice versa. The off time is the period of time that one spark is replaced by another. A longer off time permits the dielectric fluid to flush through a nozzle to clean out the eroded debris, thereby avoiding a short circuit. These settings are adjusted in micro seconds. WIRE EDM : In WIRE ELECTRICAL DISCHARGE MACHINING (WEDM), also called WIRE-CUT EDM or WIRE CUTTING, we feed a thin single-strand metal wire of brass through the workpiece, which is submerged in a tank of dielectric fluid. Wire EDM is an important variation of EDM. We occasionally use wire-cut EDM to cut plates as thick as 300mm and to make punches, tools, and dies from hard metals that are difficult to machine with other manufacturing methods. In this process which resembles to contour cutting with a band saw, the wire, which is constantly fed from a spool, is held between upper and lower diamond guides. The CNC-controlled guides move in the x–y plane and the upper guide can also move independently in the z–u–v axis, giving rise to the ability to cut tapered and transitioning shapes (such as circle on the bottom and square at the top). The upper guide can control axis movements in x–y–u–v–i–j–k–l–. This allows the WEDM to cut very intricate and delicate shapes. The average cutting kerf of our equipment that achieves the best economic cost and machining time is 0.335 mm using Ø 0.25 brass, copper or tungsten wire. However the upper and lower diamond guides of our CNC equipment are accurate to about 0.004 mm, and can have a cutting path or kerf as small as 0.021 mm using Ø 0.02 mm wire. So really narrow cuts are possible. The cutting width is greater than the width of the wire because sparking occurs from the sides of the wire to the workpiece, causing erosion. This ''overcut'' is necessary, for many applications it is predictable and therefore can be compensated for ( in micro-EDM this is not often the case). The wire spools are long—an 8 kg spool of 0.25 mm wire is just over 19 kilometers in length. Wire diameter can be as small as 20 micrometres and the geometry precision is in the neighborhood of +/- 1 micrometer. We generally use the wire only once and recycle it because it is relatively inexpensive. It travels at a constant velocity of 0.15 to 9m/min and a constant kerf (slot) is maintained during a cut. In the wire-cut EDM process we use water as the dielectric fluid, controlling its resistivity and other electrical properties with filters and de-ionizer units. The water flushes the cut debris away from the cutting zone. Flushing is an important factor in determining the maximum feed rate for a given material thickness and therefore we keep it consistent. Cutting speed in wire EDM is stated in terms of the cross-sectional area cut per unit time, such as 18,000 mm2/hr for 50mm thick D2 tool steel. The linear cutting speed for this case would be 18,000/50 = 360mm/hr The material removal rate in wire EDM is: MRR = Vf x h x b Here MRR is in mm3/min, Vf is the feed rate of the wire into workpiece in mm/min, h is thickness or height in mm, and b is the kerf, which is: b = dw + 2s Here dw is wire diameter and s is gap between wire and workpiece in mm. Along with tighter tolerances, our modern multi axis EDM wire-cutting machining centers have added features such as multi heads for cutting two parts at the same time, controls for preventing wire breakage, automatic self-threading features in case of wire breakage, and programmed machining strategies to optimize the operation, straight and angular cutting capabilities. Wire-EDM offers us low residual stresses, because it does not require high cutting forces for removal of material. When the energy/power per pulse is relatively low (as in finishing operations), little change in the mechanical properties of a material is expected due to low residual stresses. ELECTRICAL-DISCHARGE GRINDING (EDG) : The grinding wheels do not contain abrasives, they are made of graphite or brass. Repetitive sparks between the rotating wheel and workpiece remove material from workpiece surfaces. The material removal rate is: MRR = K x I Here MRR is in mm3/min, I is current in Amperes, and K is workpiece material factor in mm3/A-min. We frequently use electrical-discharge grinding to saw narrow slits on components. We sometimes combine EDG (Electrical-Discharge Grinding) process with ECG (Electrochemical Grinding) process where material is removed by chemical action, the electrical discharges from the graphite wheel breaking up the oxide film and washed away by the electrolyte. The process is called ELECTROCHEMICAL-DISCHARGE GRINDING (ECDG). Even though the ECDG process consumes relatively more power, it is a faster process than the EDG. We mostly grind carbide tools using this technique. Applications of Electrical Discharge Machining: Prototype production: We use the EDM process in mold-making, tool and die manufacturing, as well as for making prototype and production parts, especially for the aerospace, automobile and electronics industries in which production quantities are relatively low. In Sinker EDM, a graphite, copper tungsten or pure copper electrode is machined into the desired (negative) shape and fed into the workpiece on the end of a vertical ram. Coinage die making: For the creation of dies for producing jewelry and badges by the coinage (stamping) process, the positive master may be made from sterling silver, since (with appropriate machine settings) the master is significantly eroded and is used only once. The resultant negative die is then hardened and used in a drop hammer to produce stamped flats from cutout sheet blanks of bronze, silver, or low proof gold alloy. For badges these flats may be further shaped to a curved surface by another die. This type of EDM is usually performed submerged in an oil-based dielectric. The finished object may be further refined by hard (glass) or soft (paint) enameling and/or electroplated with pure gold or nickel. Softer materials such as silver may be hand engraved as a refinement. Drilling of Small Holes: On our wire-cut EDM machines, we use small hole drilling EDM to make a through hole in a workpiece through which to thread the wire for the wire-cut EDM operation. Separate EDM heads specifically for small hole drilling are mounted on our wire-cut machines which allow large hardened plates to have finished parts eroded from them as needed and without pre-drilling. We also use small hole EDM to drill rows of holes into the edges of turbine blades used in jet engines. Gas flow through these small holes allows the engines to use higher temperatures than otherwise possible. The high-temperature, very hard, single crystal alloys these blades are made of makes conventional machining of these holes with high aspect ratio extremely difficult and even impossible. Other application areas for small hole EDM is to create microscopic orifices for fuel system components. Besides the integrated EDM heads, we deploy stand-alone small hole drilling EDM machines with x–y axes to machine blind or through holes. EDM drills bore holes with a long brass or copper tube electrode that rotates in a chuck with a constant flow of distilled or deionized water flowing through the electrode as a flushing agent and dielectric. Some small-hole drilling EDMs are able to drill through 100 mm of soft or even hardened steel in less than 10 seconds. Holes between 0.3 mm and 6.1 mm can be achieved in this drilling operation. Metal disintegration machining: We also have special EDM machines for the specific purpose of removing broken tools (drill bits or taps) from work pieces. This process is called ''metal disintegration machining''. Advantages and Disadvantages Electrical-Discharge Machining: Advantages of EDM include machining of: - Complex shapes that would otherwise be difficult to produce with conventional cutting tools - Extremely hard material to very close tolerances - Very small work pieces where conventional cutting tools may damage the part from excess cutting tool pressure. - There is no direct contact between tool and work piece. Therefore delicate sections and weak materials can be machined without any distortion. - A good surface finish can be obtained. - Very fine holes can be easily drilled. Disadvantages of EDM include: - The slow rate of material removal. - The additional time and cost used for creating electrodes for ram/sinker EDM. - Reproducing sharp corners on the workpiece is difficult due to electrode wear. - Power consumption is high. - ''Overcut'' is formed. - Excessive tool wear occurs during machining. - Electrically non-conductive materials can be machined only with specific set-up of the process. КЛИКНЕТЕ Услуга за пронаоѓање на производи-локатор ПРЕТХОДНА СТРАНИЦА

Automation and Intelligent Systems, Artificial Intelligence, AI, Embedded Systems, Internet of Things, IoT, Industrial Control Systems, Automatic Control, Janz Автоматизација и интелигентни системи AUTOMATION also referred to as AUTOMATIC CONTROL, is the use of various CONTROL SYSTEMS for operating equipment such as factory machines, heat treating and curing ovens, telecommunication equipment, …etc. with minimal or reduced human intervention. Automation is achieved by using various means including mechanical, hydraulic, pneumatic, electrical, electronic and computers in combination. An INTELLIGENT SYSTEM on the other hand is a machine with an embedded, Internet-connected computer that has the capability to gather and analyze data and communicate with other systems. Intelligent systems require security, connectivity, ability to adapt according to current data, capability for remote monitoring and management. EMBEDDED SYSTEMS are powerful and capable of complex processing and data analysis usually specialized for tasks relevant to the host machine. Intelligent systems are all around in our daily lives. Examples are traffic lights, smart meters, transportation systems and equipment, digital signage. Some brand name products we sell are ATOP TECHNOLOGIES, JANZ TEC, KORENIX, ICP DAS, DFI-ITOX. AGS-TECH Inc. offers you products that you can readily purchase from stock and integrate into your automation or intelligent system as well as custom products designed specifically for your application. As the most diverse ENGINEERING INTEGRATION provider we pride ourselves with our capability to provide a solution for almost any automation or intelligent system needs. Besides products, we are here for your consulting and engineering needs. CLICK ON BLUE COLORED TEXT BELOW TO DOWNLOAD OUR PRODUCT BROCHURES AND CATALOGS: - ATOP TECHNOLOGIES compact product brochure - ATOP Technologies Product List 2021) - Barcode and Fixed Mount Scanners - RFID Products - Mobile Computers - Micro Kiosks OEM Technology (We private label these with your brand name and logo if you wish) - Barcode Scanners (We private label these with your brand name and logo if you wish) - Catalog for Vandal-Proof IP65/IP67/IP68 Keyboards, Keypads, Pointing Devices, ATM Pinpads, Medical & Military Keyboards and other similar Rugged Computer Peripherals - DFI-ITOX brand embedded single board computers brochure - Fixed Industrial Scanners (We private label these with your brand name and logo if you wish) - ICP DAS brand industrial communication and networking products brochure - ICP DAS brand Industrial Touch Pad brochure - ICP DAS brand machine automation brochure - ICP DAS brand PACs Embedded Controllers & DAQ brochure - ICP DAS brand PCI Boards and IO Cards - ICP DAS brand Remote IO Modules and IO Expansion Units brochure - JANZ TEC brand compact product brochure - 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) - KORENIX brand compact product brochure - Mobile Computers for Enterprises (We private label these with your brand name and logo if you wish) - Printers for Barcode Scanners and Mobile Computers (We private label these with your brand name and logo if you wish) - RFID Readers - Scanners - Encoders - Printers (We private label these with your brand name and logo if you wish) Dowload brochure for our DESIGN PARTNERSHIP PROGRAM Industrial control systems are computer-based systems to monitor and control industrial processes. Some of our INDUSTRIAL CONTROL SYSTEMS (ICS) are: - Supervisory Control and Data Acquisition (SCADA) Systems : These systems operate with coded signals over communication channels to provide control of remote equipment, generally using one communication channel per remote station. The control systems may be combined with data acquisition systems by adding the use of coded signals over communication channels to acquire information about the status of the remote equipment for display or for recording functions. SCADA systems are different from other ICS systems by being large-scale processes that can include multiple sites over large distances. SCADA systems can control industrial processes such as manufacturing and fabrication, infrastructure processes such as transport of oil & gas, electric power transmission, and facility-based processes such as monitoring & control of heating, ventilation, air conditioning systems. - Distributed Control Systems (DCS) : A type of automated control system that is distributed throughout a machine to provide instructions to different parts of the machine. Contrary to having a centrally located device controlling all machines, in distributed control systems each section of a machine has its own computer that controls the operation. DCS systems are commonly used in manufacturing equipment, utilizing input and output protocols to control the machine. Distributed Control Systems typically use custom designed processors as controllers. Both proprietary interconnections as well as standard communications protocols are used for communication. Input and output modules are the component parts of a DCS. Input and output signals may be either analog or digital. Buses connect the processor and modules through multiplexers and demultiplexers. They also connect the distributed controllers with the central controller and to the Human–machine interface. DCS are frequently used in: -Petrochemical and chemical plants -Power plant systems, boilers, nuclear power plants -Environmental control systems -Water management systems -Metal manufacturing plants - Programmable Logic Controllers (PLC) : A Programmable Logic Controller is a small computer with a built-in operating system made primarily to control machinery. PLCs operating systems are specialized to handle incoming events in real time. Programmable Logic Controllers can be programmed. A program is written for the PLC which turns on and off outputs based on input conditions and the internal program. PLCs have input lines where sensors are connected to notify events (such as temperature being above/below a certain level, liquid level reached,… etc.), and output lines to signal any reaction to the incoming events (such as start the engine, open or close a specific valve,… etc.). Once a PLC is programmed, it can run repeatedly as needed. PLCs are found inside of machines in industrial environments and can run automatic machines for many years with little human intervention. They are designed for harsh environments. Programmable Logic Controllers are used extensively in process-based industries, they are computer-based solid-state devices that control industrial equipment and processes. Even though PLCs can control system components used in SCADA and DCS systems, they are often the primary components in smaller control systems. CLICK Product Finder-Locator Service ПРЕТХОДНА СТРАНИЦА

Plastic Molds & Molding & Extrusion, Plastic Molding of Instrument Housing, Injection Moulded Components from PVC, PE, PET, PC Пластични калапи и обликување и истиснување Лиени пластични компоненти собрани во задно светло на мотоцикл. AGS-TECH ги произведе за клиент деловите и целото електронско склопување кое ги исполнува барањата на Одделот за транспорт. Пластични обликувани електронски футроли за очила Склоп на прецизно обликувано пластично куќиште за очила со активирано движење Поглед од дното на куќиштето за очила, обликувано со инјектирање Склоп на прецизно обликувано пластично куќиште за очила со активирано движење Калапи и склопување на пластични компоненти од AGS-TECH Inc. Коло и калап пластични компоненти собрани во медицинска печка Plastic moulding and assembly by AGS-TECH Inc Производство на пластични играчки Прецизни лајсни за вбризгување Делови со вбризгување составени заедно Лиени делови произведени од AGS-TECH на повторна основа Брзо прототипирање на пластични производи Injection molded pneumatic components FDA ги одобри производите за широка потрошувачка од екструдирана - лиена пластика од AGS-TECH FDA одобри пластични производи за храна и пијалоци од AGS-TECH Прецизни пластични екструзии од AGS-TECH Производство на пластични екструзии и истиснување во AGS-TECH UHMWPE ленти за носење екструдирани UHMW PE патеки - Пластично обликување и истиснување во AGS-TECH Inc UHMW PE патеки - Пластични екструзии во AGS-TECH Inc Blow Molded Recovery Coolant Tank by AGS-TECH. Калапи со вбризгување на различни контејнери - AGS-TECH Inc. UHMWPE Extrusion Parts - AGS-TECH Inc Пластична подлога со обликуван столб од AGS-TECH Inc. Калапи со вбризгување и дување за производство на футроли за носење инструменти - AGS-TECH Inc. Калапи со дување во AGS-TECH Inc. Калапи за дување за пластични садови - AGS-TECH Inc. ПРЕТХОДНА СТРАНИЦА

Industrial Computer Accessories, PCI, Peripheral Component Interconnect, Multichannel Analog & Digital Input Output Modules, Relay Module, Printer Interface Додатоци, модули, табли за носачи за индустриски компјутери A PERIPHERAL DEVICE is one attached to a host computer, but not part of it, and is more or less dependent on the host. It expands the host's capabilities, but does not form part of the core computer architecture. Examples are computer printers, image scanners, tape drives, microphones, loudspeakers, webcams, and digital cameras. Peripheral devices connect to the system unit through the ports on the computer. CONVENTIONAL PCI (PCI stands for PERIPHERAL COMPONENT INTERCONNECT, part of the PCI Local Bus standard) is a computer bus for attaching hardware devices in a computer. These devices can take either the form of an integrated circuit fitted onto the motherboard itself, called a planar device in the PCI specification, or an expansion card that fits into a slot. We carry name brands such as JANZ TEC, DFI-ITOX and KORENIX. Click on blue highlighted text to download brochure or catalog: - Catalog for Vandal-Proof IP65/IP67/IP68 Keyboards, Keypads, Pointing Devices, ATM Pinpads, Medical & Military Keyboards and other similar Rugged Computer Peripherals - DFI-ITOX brand Industrial Computer Peripherals - DFI-ITOX brand Graphics Cards - DFI-ITOX brand Industrial Motherboards brochure - DFI-ITOX brand embedded single board computers brochure - DFI-ITOX brand computer-on-board modules brochure - DFI-ITOX brand Embedded OS Services - ICP DAS brand industrial communication and networking products brochure - ICP DAS brand PACs Embedded Controllers & DAQ brochure - ICP DAS brand Industrial Touch Pad brochure - ICP DAS brand Remote IO Modules and IO Expansion Units brochure - ICP DAS brand PCI Boards and IO Cards - JANZ TEC brand compact product brochure - KORENIX brand compact product brochure - Private Label Flash Storage for Embedded Industrial Applications (We can put your name, logo, brand on these.............) To choose a suitable component or accessory for your projects. please go to our industrial computer store by CLICKING HERE. Dowload brochure for our DESIGN PARTNERSHIP PROGRAM Some of the components and accessories we offer for industrial computers are: - Multichannel analog and digital input output modules : We offer hundreds of different 1-, 2-, 4-, 8-, 16-channel function modules. They do have compact size and this small size makes these systems easy to use in confined places. Up to 16 channels can be accommodated in a 12mm (0.47in) wide module. Connections are pluggable, secure and strong, making replacing easy for the operators while the spring pressure technology assures continuous operation even under severe environmental conditions such as shock/vibration, temperature cycling….etc. Our multichannel analog and digital input output modules are highly flexible that each node in the I/O system can be configured to meet each channel’s requirements, digital and analog I/O and others can be easily combined. They are easy to handle, the modular rail-mounted module design allows easy and tool-free handling and modifications. Using colored markers the functionality of individual I/O modules is identified, terminal assignment and technical data are printed onto the side of the module. Our modular systems are fieldbus-independent. - Multichannel relay modules : A relay is a switch controlled by an electric current. Relays make it possible for a low voltage low current circuit to switch a high voltage / high current device safely. As an example, we can use a battery powered small light detector circuit to control large mains powered lights using a relay. Relay boards or modules are commercial circuit boards fitted with relays, LED indicators, back EMF preventing diodes and practical screw-in terminal connections for voltage inputs, NC, NO, COM connections on the relay at the least. Multiple poles on them make it possible to switch multiple devices on or off simultaneously. Most industrial projects require more than one relay. Therefore multi-channel or also known as multiple relay boards are offered. They can have anywhere from 2 to 16 relays on the same circuit board. Relay boards can also be computer controlled directly by USB or serial connection. Relay boards connected to LAN or internet connected PC, we can control relays remotely from far away distances using special software. - Printer interface: A printer interface is a combination of hardware and software that allows the printer to communicate with a computer. The hardware interface is called port and each printer has at least one interface. An interface incorporates several components including its communication type and the interface software. There are eight major communication types: 1. Serial : Through serial connections computers send one bit of information at a time, one after another. Communication parameters such as parity, baud should be set on both entities before communication takes place. 2. Parallel : Parallel communication is more popular with printers because it is faster compared to serial communication. Using parallel type communication, printers receive eight bits at a time over eight separate wires. Parallel uses a DB25 connection on the computer side and an oddly shaped 36 pin connection on the printer side. 3. Universal Serial Bus (popularly referred to as USB) : They can transfer data fast with a transfer rate of up to 12 Mbps and automatically recognize new devices. 4. Network : Also commonly referred to as Ethernet, network connections are commonplace on network laser printers. Other types of printers also employ this type of connection. These printers have a Network Interface Card (NIC) and ROM-based software that allows them to communicate with networks, servers and workstations. 5. Infrared : Infrared transmissions are wireless transmissions that use infrared radiation of the electromagnetic spectrum. An Infrared acceptor allows your devices (laptops, PDA’s, Cameras, etc) connect to the printer and send print commands through infrared signals. 6. Small Computer System Interface (known as SCSI) : Laser printers and some others use SCSI interfaces to PC as there is the benefit of daisy chaining wherein multiple devices could be on a single SCSI connection. Its implementation is easy. 7. IEEE 1394 Firewire : Firewire is a high speed connection widely used for digital video editing and other high bandwidth requirements. This interface currently supports devices with a maximum throughput of 800 Mbps and capable of speeds up to 3.2 Gbps. 8. Wireless : Wireless is the currently popular technology like infrared and bluetooth. The information is transmitted wirelessly through the air using radio waves and is received by the device. Bluetooth is used to replace the cables between computers and its peripherals and they usually work over small distances of about 10 meters. Out of these above communication types scanners mostly use USB, Parallel, SCSI, IEEE 1394/FireWire. - Incremental Encoder Module : Incremental encoders are used in positioning and motor speed feedback applications. Incremental encoders provide excellent speed and distance feedback. As few sensors are involved, the incremental encoder systems are simple and economical. An incremental encoder is limited by only providing change information and therefore the encoder requires a reference device to calculate motion. Our incremental encoder modules are versatile and customizable to fit a variety of applications such as heavy duty applications as is the case in pulp & paper, steel industries; industrial duty applications such as textile, food, beverage industries and light duty/servo applications such as robotics, electronics, semiconductor industry. - Full-CAN Controller For MODULbus Sockets : The Controller Area Network, abbreviated as CAN was introduced to address the growing complexity of vehicle functions and networks. In the first embedded systems, modules contained a single MCU, performing a single or multiple simple functions such as reading a sensor level via an ADC and controlling a DC motor. As functions became more complex, designers adopted distributed module architectures, implementing functions in multiple MCUs on the same PCB. According to this example, a complex module would have the main MCU performing all system functions, diagnostics, and failsafe, while another MCU would handle a BLDC motor control function. This was made possible with the wide availability of general purpose MCUs at a low cost. In today’s vehicles, as functions become distributed within a vehicle rather than a module, the need for a high fault tolerance, inter module communication protocol led to the design and introduction of CAN in the automotive market. Full CAN Controller provides an extensive implementation of message filtering, as well as message parsing in the hardware, thus releasing the CPU from the task of having to respond to every received message. Full CAN controllers can be configured to interrupt the CPU only when messages whose Identifiers have been setup as acceptance filters in the controller. Full CAN controllers are also setup with multiple message objects referred to as mailboxes, which can store specific message information such as ID and data bytes received for the CPU to retrieve. The CPU in this case would retrieve the message any time, however, must complete the task prior to an update of that same message is received and overwrites the current content of the mailbox. This scenario is resolved in the final type of CAN controllers. Extended Full CAN controllers provide an additional level of hardware implemented functionality, by providing a hardware FIFO for received messages. Such an implementation allows more than one instance of the same message to be stored before the CPU is interrupted therefore preventing any information loss for high frequency messages, or even allowing the CPU to focus on the main module function for a longer period of time. Our Full-CAN Controller for MODULbus Sockets offers the following features: Intel 82527 Full CAN controller, Supports CAN protocol V 2.0 A and A 2.0 B, ISO/DIS 11898-2, 9-pin D-SUB connector, Options Isolated CAN interface, Supported Operating Systems are Windows, Windows CE, Linux, QNX, VxWorks. - Intelligent CAN Controller For MODULbus Sockets : We offer our clients local intelligence with MC68332, 256 kB SRAM / 16 bit wide, 64 kB DPRAM / 16 bit wide, 512 kB flash, ISO/DIS 11898-2, 9-pin D-SUB connector, ICANOS firmware on-board, MODULbus+ compatible, options such as isolated CAN interface, CANopen available, operating systems supported are Windows, Windows CE, Linux, QNX, VxWorks. - Intelligent MC68332 Based VMEbus Computer : VMEbus standing for VersaModular Eurocard bus is a computer data path or bus system that is used in industrial, commercial and military applications worldwide. VMEbus is used in traffic control systems, weapons control systems, telecommunication systems, robotics, data acquisition, video imaging...etc. VMEbus systems withstand shock, vibration and extended temperatures better than the standard bus systems used in desktop computers. This makes them ideal for harsh environments. Double euro-card from factor (6U) , A32/24/16:D16/08 VMEbus master; A24:D16/08 slave interface, 3 MODULbus I/O sockets, front-panel and P2 connection of MODULbus I/O lines, programmable MC68332 MCU with 21 MHz, on-board system controller with first slot detection, interrupt handler IRQ 1 – 5, interrupt generator any 1 of 7, 1 MB SRAM main memory, up to 1 MB EPROM, up to1 MB FLASH EPROM, 256 kB dual-ported battery buffered SRAM, battery buffered realtime clock with 2 kB SRAM, RS232 serial port , periodic interrupt timer (internal to MC68332), watchdog timer (internal to MC68332), DC/DC converter to supply analog modules. Options are 4 MB SRAM main memory. Supported operating system is VxWorks. - Intelligent PLC Link Concept (3964R) : A programmable logic controller or briefly PLC is a digital computer used for automation of industrial electromechanical processes, such as control of machinery on factory assembly lines and amusement rides or light fixtures. PLC Link is a protocol to share easily memory area between two PLC’s. The big advantage of PLC Link is to work with PLC’s as Remote I/O units. Our Intelligent PLC Link Concept offers communication procedure 3964®, a messaging interface between host and firmware through software driver, applications on the host to communicate with another station on the seriel line connection, serial data communication according to 3964® protocol, availability of software drivers for various operating systems. - Intelligent Profibus DP Slave Interface : ProfiBus is a messaging format specifically designed for high-speed serial I/O in factory and building automation applications. ProfiBus is an open standard and is recognized as the fastest FieldBus in operation today, based on RS485 and the European EN50170 Electrical Specification. The DP suffix refers to ''Decentralized Periphery'', which is used to describe distributed I/O devices connected via a fast serial data link with a central controller. To the contrary, a programmable logic controller, or PLC described above normally has its input/output channels arranged centrally. By introducing a network bus between the main controller (master) and its I/O channels (slaves), we have decentralized the I/O. A ProfiBus system uses a bus master to poll slave devices distributed in multi-drop fashion on an RS485 serial bus. A ProfiBus slave is any peripheral device (such as an I/O transducer, valve, network drive, or other measuring device) which processes information and sends its output to the master. The slave is a passively operating station on the network since it does not have bus access rights and can only acknowledge received messages, or send response messages to the master upon request. It is important to note that all ProfiBus slaves have the same priority, and that all network communication originates from the master. To summarize: A ProfiBus DP is an open standard based on EN 50170, it is the fastest Fieldbus standard to date with data rates up to 12 Mb, offers plug and play operation, enables up to 244 bytes of input/output data per message, up to 126 stations may connect to the bus and up to 32 stations per bus segment. Our Intelligent Profibus DP Slave Interface Janz Tec VMOD-PROFoffers all functions for motor controlling of DC servo motors, programmable digital PID filter, velocity, target position and filter parameters that are changeable during motion, quadrature encoder interface with pulse input, programmable host interrupts, 12 bit D/A converter, 32 bit position, velocity and acceleration registers. It support Windows, Windows CE, Linux, QNX and VxWorks operating systems. - MODULbus Carrier Board for 3 U VMEbus Systems : This system offers 3 U VMEbus non-intelligent carrier board for MODULbus, single euro-card form factor (3 U), A24/16:D16/08 VMEbus slave interface, 1 socket for MODULbus I/O, jumper selectable interrupt level 1 – 7 and vector-interrupt, short-I/O or standard-addressing, needs only one VME-slot, supports MODULbus+identification mechanism, front panel connector of I/O signals (provided by modules). Options are DC/DC converter for analog module power supply. Supported operating systems are Linux, QNX, VxWorks. - MODULbus Carrier Board For 6 U VMEbus Systems : This system offers 6U VMEbus non-intelligent carrier board for MODULbus, double euro-card, A24/D16 VMEbus slave interface, 4 plug-in sockets for MODULbus I/O, different vector from each MODULbus I/O, 2 kB short-I/O or standard-address range, needs only one VME-slot, front panel and P2 connection of I/O lines. Options are DC/DC converter to supply analog modules power. Supported operating systems are Linux, QNX, VxWorks. - MODULbus Carrier Board For PCI Systems : Our MOD-PCI carrier boards offer non-intelligent PCI with two MODULbus+ sockets, extended height short form factor, 32 bit PCI 2.2 target interface (PLX 9030), 3.3V / 5V PCI interface, only one PCI-bus slot occupied, front panel connector of MODULbus socket 0 available at PCI bus bracket. On the other hand, our MOD-PCI4 boards have non-Intelligent PCI-bus carrier board with four MODULbus+ sockets, extended height long form factor, 32 bit PCI 2.1 target interface (PLX 9052), 5V PCI interface, only one PCI slot occupied, front panel connector of MODULbus socket 0 available at ISAbus bracket, I/O connector of MODULbus socket 1 available on 16-pin flat cable connector at ISA bracket. - Motor Controller For DC Servo Motors : Mechanical systems manufacturers, power & energy equipment producers, transportation & traffic equipment producers and service companies, automotive, medical and many other areas can use our equipment with peace of mind, because we offer robust, reliable and scalable hardware for their drive technology. The modular design of our motor controllers enables us to offer solutions based on emPC systems that are highly flexible and ready to be adapted to customer’s requirements. We are able to design interfaces that are economical and suitable for applications ranging from simple single axis to multiple synchronized axes. Our modular and compact emPCs can be complemented with our scalable emVIEW displays (currently from 6.5” to 19”) for a broad spectrum of applications ranging from simple control systems to integral operator interface systems. Our emPC systems are available in different performance classes and sizes. They have no fans and work with compact-flash media. Our emCONTROL soft PLC environment can be used as a fully fledged, real-time control system enabling both simple as well as complex DRIVE ENGINEERING tasks to be accomplished. We also customize our emPC to meet your specific requirements. - Serial Interface Module : A Serial Interface Module is a device that creates an addressable zone input for a conventional detection device. It offers a connection to an addressable bus, and a supervised zone input. When the zone input is open, the module sends status data to the control panel indicating the open position. When the zone input is shorted, the module sends status data to the control panel, indicating the shorted condition. When the zone input is normal, the module sends data to the control panel, indicating the normal condition. Users see status and alarms from the sensor at the local keypad. The control panel can also send a message to the monitoring station. The serial interface module can be used in alarm systems, building control and energy management systems. Serial interface modules provide important advantages reducing installation labor by its special designs, by providing an addressable zone input, reducing the overall cost of the entire system. Cabling is minimal because the module’s data cable need not be individually routed to the control panel. The cable is an addressable bus that allows connection to many devices before cabling and connecting to the control panel for processing. It saves current, and minimizes the need for additional power supplies because of its low current requirements. - VMEbus Prototyping Board : Our VDEV-IO boards offer double Eurocard form factor (6U) with VMEbus interface, A24/16:D16 VMEbus slave interface, full interruption capabilities, pre-decoding of 8 address ranges, vector register, large matrix field with surrounding track for GND/Vcc, 8 user definable LEDs at the front panel. КЛИКНЕТЕ Услуга за пронаоѓање на производи-локатор ПРЕТХОДНА СТРАНИЦА