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Test Equipment for Textiles Testing, Air Permeability Tester, Elmendorf Tearing Tester, Rubbing Fastness Tester for Textile, Spray Rate Tester Тест опрема за тестирање на текстил Specialized Test Equipment for Textiles Testing are used for testing textile products such as fabric and clothes, for checking their quality, endurance, functionality, reliability, safety, compliance to domestic and international standards....etc. Our specialized test equipment can be either: - CUSTOM DESIGNED and MANUFACTURED SPECIALIZED TEST EQUIPMENT for TEXTILES TESTING or - OFF-SHELF SPECIALIZED TEST EQUIPMENT for TEXTILES TESTING Custom designed specialized testing equipment is designed and developed by us for our customers specific needs, taking into consideration our customers specific requirements, their markets, their legal responsibilities...etc. We work with you hand in hand to accomplish what you need and want. Our engineers design, prototype and get your approval prior to manufacturing your test machines. On the other hand, our off-shelf specialized test equipment for testing of textiles are already designed and manufactured systems that can be purchased quickly from us and used. If you let us know what you need, we will be happy to guide you and propose you ready systems that can help achieve your goals. Our off-shelf specialized test equipment for testing of textiles can be downloaded from the colored links below: HAIDA Air Permeability Tester HAIDA Automatic Bursting Strength Test Machine Catalog Download HAIDA Automatic Wrap Reel for Textile HAIDA Bursting Strength Tester Series HAIDA Color Assessment Cabinet HAIDA Color Fastness to Washing Tester 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 Elmendorf Tearing Tester HAIDA Extra - Height Tensile Test Machine HAIDA Ironing Sublimation Color Fastness HAIDA Needle Detector HAIDA Rubbing Fastness Tester for Textile HAIDA Spray Rate Tester HAIDA Tensile Test Machines HAIDA Universal Testing Machine HAIDA Universal Test Machine HAIDA Universal Test Machine with Temperature Chamber За друга слична опрема, посетете ја нашата веб-страница за опрема: http://www.sourceindustrialsupply.com КЛИКНЕТЕ Услуга за пронаоѓање на производи-локатор ПРЕТХОДНА СТРАНИЦА

Electronic Assembly, Cable Harness, PCBA, PCB, Optoelectronic Manufacturing, Transformer Assembly, Motion Detector Електрични и електронски склопови Електронско собрание - AGS-TECH, Inc. Електронско склопување на медицинска печка Производство и монтажа на електронски производи од AGS-TECH, Inc. Капацитивен кабел за слушалки на допир развиен и произведен од AGS-TECH Inc. Развој и производство на капацитивен кабел за слушалки на допир Оптоелектронски PCBA ПХБ плочи Прилагодени склопови на ПХБ од AGS-TECH Прототип на оптоелектронски робот со ротирачка и навалена етапа за автоматско следење и снимање Прилагодено произведен и склопен трансформатор Прилагодени трансформатори произведени од AGS-TECH Склопување на електрична дупчалка од AGS-TECH Inc. Трансформатори прилагодено произведени од AGS-TECH за производител на скара PCBA склопови - Електрични електронски склопови Футрола за очила со детектори за движење AGS-TECH, Inc. Куќиште за очила со сензори за движење целосно произведено и склопено од AGS-TECH, Inc. AGS-TECH ги пакува вашите производи по ваш избор и потреби Склопување на алтернатор од AGS-TECH Inc. Почетно собрание од AGS-TECH Inc. Електричен стартер од AGS-TECH Inc. ПХБ и СМТ собранија AGS-TECH Inc. Мерачи на деформација со жичени кабли произведени и составени од AGS-TECH Inc. Еднослојни и повеќеслојни ПХБ плочи достапни од AGS-TECH Inc Плоча со печатено коло склопува PCBA Прилагодено производство на PCBA AGS-TECH, Inc. Производство на ПХБ плоча AGS-TECH Ние произведуваме склопови на печатени кола според вашиот дизајн или нашиот дизајн прилагоден на вашите потреби ПРЕТХОДНА СТРАНИЦА

Rubber and Elastomer Molds & Molding, Rubber Injection Molding, Rubber Toy Manufacturing Калапи и калапи од гума и еластомер Дел од калап со вбризгување на гума склопен со други метални делови. Ние ги правиме калапите и алатките за производство на ваши сопствени делови. Механички склоп со гумена компонента обликувана со инјектирање. Целото склопување беше произведено од AGS-TECH Inc. Гумени играчки произведени од AGS-TECH Inc. Делови по мерка изработени од голем избор на гумени материјали Прилагодено гумено обликување на автомобилски душеци за еден од нашите клиенти - AGS-TECH Inc - Посетете не на www.agstech.net Лиени гумени компоненти собрани во спортски производи. Сите компоненти произведени и составени од AGS-TECH Inc. Rubber Belts Manufacturing by AGS-TECH Inc. Производство на О-прстен во AGS-TECH Inc. Лиен О-прстен комплети Екструдирани гумени делови од EPDM - NBR - CR - SILICONE - PVC - TPE - TPV Екструзија на гума од EPDM - NBR - CR - SILICONE - PVC - TPE - TPV изработена од AGS-TECH Екструзија од EPDM - NBR - CR - SILICONE - PVC - TPE - TPV Лиени гумени делови од EPDM - NBR - CR - SILICONE - PVC - TPE - TPV Екструдирана гума изработена од EPDM - NBR - CR - SILICONE - PVC - TPE - TPV ПРЕТХОДНА СТРАНИЦА

Waterjet Machining - WJ Cutting - Abrasive Water Jet - Hydrodynamic Machining - WJM - AWJM - AJM - AGS-TECH Inc. - USA Waterjet Machining & Abrasive Waterjet & Abrasive-Jet Machining and Cutting The principle of operation of WATER-JET, ABRASIVE WATER-JET and ABRASIVE-JET MACHINING & CUTTING is based on momentum change of the fast flowing stream that hits the workpiece. During this momentum change, a strong force acts and cuts the workpiece. These WATERJET CUTTING & MACHINING (WJM) techniques are based on water and highly refined abrasives, propelled at three times the speed of sound, to make incredibly accurate and precise cuts in virtually any material. For some materials like leather and plastics, an abrasive may be omitted and cutting can be done only with water. Waterjet machining can do things that other techniques cannot, from cutting intricate, very thin details in stone, glass and metals; to rapid hole drilling of titanium. Our waterjet cutting machines can handle large flat stock material with many feet of dimensions with no limit to the type of material. To make cuts and manufacture parts, we can scan images from files into the computer or a Computer Aided Drawing (CAD) of your project can be prepared by our engineers. We need to determine the type of material being cut, its thickness, and the desired cut quality. Intricate designs present no problem as the nozzle simply follows the rendered image pattern. Designs are limited only by your imagination. Contact us today with your project and let us give you our suggestions and quote. Let us examine these three types of processes in detail. WATER-JET MACHINING (WJM): The process may equally be called HYDRODYNAMIC MACHINING. The highly localized forces from the water-jet are used for cutting and deburring operations. In simpler words, the water jet acts like a saw that cuts a narrow and smooth groove in the material. Pressures levels in waterjet-machining are around 400 MPa which is pretty sufficient for efficient operation. If needed, pressures that are a few times this value can be generated. The diameters of jet nozzles are in the neighborhood of 0.05 to 1mm. We cut a variety of nonmetallic materials such as fabrics, plastics, rubber, leather, insulating materials, paper, composite materials using the waterjet cutters. Even complicated shapes such as automotive dashboard coverings made of vinyl and foam can be cut using multiple-axis, CNC controlled waterjet machining equipment. Waterjet machining is an efficient and clean process when compared to other cutting processes. Some of the major advantages of this technique are: -Cuts can be started at any location on the work piece without the need to predrill holes. -No significant heat is produced -The waterjet machining and cutting process is well suited for flexible materials because no deflection and bending of the workpiece takes place. -The burrs produced are minimal -Water-jet cutting and machining is an environmentally friendly and safe process that uses water. ABRASIVE WATER-JET MACHINING (AWJM): In this process, abrasive particles such as silicon carbide or aluminum oxide are contained in the water jet. This increases the material removal rate over that of purely water-jet machining. Metallic, nonmetallic, composite materials and others can be cut using AWJM. The technique is particularly useful for us in cutting heat-sensitive materials that we cannot cut using other techniques that produce heat. We can produce minimum holes of 3mm size and maximum depths of about 25 mm. Cutting speed can reach as high as several meters per minute depending on material being machined. For metals the cutting speed in AWJM is less as compared to plastics. Using our multiple-axis robotic control machines we can machine complex three-dimensional parts to finish dimensions without the need for a second process. To keep nozzle dimensions and diameter constant we use sapphire nozzles which is important in keeping accuracy and repeatability of the cutting operations. ABRASIVE-JET MACHINING (AJM) : In this process a high-velocity jet of dry air, nitrogen or carbondioxide containing abrasive particles hits and cuts the workpiece under controlled conditions. Abrasive-Jet Machining is used for cutting small holes, slots and intricate patterns in very hard and brittle metallic and nonmetallic materials, deburring and removing flash from parts, trimming and beveling, removing surface films such as oxides, cleaning of components with irregular surfaces. The gas pressures are around 850 kPa, and the abrasive-jet velocities around 300 m/s. Abrasive particles have diameters around 10 to 50 microns. The high speed abrasive particles round off sharp corners and holes made tend to be tapered. Therefore designers of parts that will be machined by abrasive-jet should take these into consideration and make sure the produced parts do not require such sharp corners and holes. The water-jet, abrasive water-jet and abrasive-jet machining processes can be used effectively for cutting and deburring operations. These techniques have an inherent flexibility thanks to the fact that they do not use hard tooling. КЛИКНЕТЕ Услуга за пронаоѓање на производи-локатор ПРЕТХОДНА СТРАНИЦА

Drive and Driving Shafts Manufacturing - Propeller Prop Cardan Shaft, Drive Train, Splined Shaft, Tapered Shaft, Assembly - AGS-TECH Inc., New Mexico - USA Shafts Manufacturing A drive shaft, driveshaft, driving shaft, propeller shaft (prop shaft), or Cardan shaft is defined as a mechanical component for transmitting rotation and torque, generally deployed to connect other components of a drive train that cannot be connected directly because of distance or the need to allow for relative movement between them. Generally speaking, there are mainly two types of shafts: Transmission shafts are used to transmit power between the source and the machine absorbing power; e.g. counter shafts and line shafts. On the other hand, machine shafts are the integral part of the machine itself; e.g. crankshaft. To allow for variations in the alignment and distance between the driving and driven components, drive shafts frequently incorporate one or more universal joints, jaw couplings, rag joints, a splined joint or a prismatic joint. We sell shafts for transportation industry, industrial machinery, work equipment. According to your application, the proper material is chosen with appropriate weight and strength. While some applications require lightweight shafts for lower inertia, others necessitate very strong materials to stand the extremely high torques and weight. Call us today to discuss your application. We use a variety of techniques to assemble shafts with their mating parts. According to the environment and application, here are a few of our techniques for engaging shafts and their mating parts: SPLINED SHAFT: These shafts have multiple grooves, or key-seats cut around its circumference for a portion of its length in order that a sliding engagement may be made with corresponding internal grooves of a mating part. TAPERED SHAFT: These shafts have a tapered end for easy and strong engagement with the mating part. Shafts may also be connected to their mating parts by other means such as setscrews, press fit, sliding fit, slip fit with key, pins, knurled joint, driven key, brazed joint…etc. SHAFT & BEARING & PULLEY ASSEMBLY: This is another area where we have the expertise to manufacture reliable assemblies of bearings and pulleys with shafts. SEALED SHAFTS: We seal shafts and shaft assemblies for grease and oil lubrication and protection from dirty environments. MATERIALS USED FOR MANUFACTURING SHAFTS: The materials we use for ordinary shafts is mild steel. When high strength is required, an alloy steel such as nickel, nickel-chromium or chromium-vanadium steel is used. We form shafts generally by hot rolling and finish them to size by cold drawing or turning and grinding. OUR STANDARD SHAFT SIZES: Machine shafts Up to 25 mm steps of 0.5 mm Between 25 to 50 mm steps of 1 mm Between 50 to 100 mm steps of 2 mm Between 100 to 200 mm steps of 5 mm Transmission shafts Between 25 mm to 60 mm with 5 mm steps Between 60 mm to 110 mm with 10 mm steps Between 110 mm to 140 mm with 15 mm steps Between 140 mm to 500 mm with 20 mm steps The standard lengths of the shafts are 5 m, 6 m and 7 m. Please click on highlighted text below to download our relevant catalogs and brochures on off-shelf shafts: - Round and square shafts for linear bearings & linear shafting КЛИКНЕТЕ Услуга за пронаоѓање на производи-локатор ПРЕТХОДНА СТРАНИЦА

Quality Management at AGS-TECH Inc. All our manufacturing operations are conducted under strict QMS guidelines, Total Quality Management TQM guidelines, SPC... Управување со квалитет во AGS-TECH Inc All plants manufacturing parts and products for AGS-TECH Inc are certified to one or several of the following QUALITY MANAGEMENT SYSTEM (QMS) standards: - ISO 9001 - TS 16949 - QS 9000 - AS 9100 - ISO 13485 - ISO 14000 Besides the above listed quality management systems, we assure our customers highest quality products and services by manufacturing according to well recognized international standards and certifications such as: - UL, CE, EMC, FCC and CSA Certification Marks, FDA Listing, DIN / MIL / ASME / NEMA / SAE / JIS /BSI / EIA / IEC / ASTM / IEEE Standards, IP, Telcordia, ANSI, NIST The specific standards that apply to a certain product depend on the nature of the product, its application field, usage and customer’s request. We see quality as an area that needs continuous improvement and therefore we never restrict ourselves with these standards only. We continuously strive to increase our quality levels at all plants and all areas, departments and product lines by focusing on: - Six Sigma - Total Quality Management (TQM) - Statistical Process Control (SPC) - Life Cycle Engineering / Sustainable Manufacturing - Robustness in Design, Manufacturing Processes and Machinery - Agile Manufacturing - Value Added Manufacturing - Computer Integrated Manufacturing - Concurrent Engineering - Lean Manufacturing - Flexible Manufacturing For those who are interested in expanding their understanding on quality, let us briefly discuss these. THE ISO 9001 STANDARD: Model for quality assurance in design/development, production, installation, and servicing. The ISO 9001 quality standard is used worldwide and is one of the most common. For initial certification as well as for timely renewals, our plants are visited and audited by accredited independent third-party teams to certify that the quality management standard’s 20 key elements are in place and functioning correctly. The ISO 9001 quality standard is not a product certification, rather a quality process certification. Our plants are periodically audited to maintain this quality standard accreditation. Registration symbolizes our commitment to conform to consistent practices, as specified by our quality system (quality in design, development, production, installation and servicing), including proper documentation of such practices. Our plants are also assured of such good quality practices by demanding our suppliers to be registered too. THE ISO/TS 16949 STANDARD: This is an ISO technical specification aimed at the development of a quality management system that provides for continual improvement, emphasizing defect prevention and the reduction of variation and waste in the supply chain. It is based on the ISO 9001 quality standard. TS16949 quality standard applies to the design/development, production and, when relevant, installation and servicing of automotive-related products. The requirements are intended to be applied throughout the supply chain. Many of AGS-TECH Inc. plants maintain this quality standard instead of or in addition to the ISO 9001. THE QS 9000 STANDARD: Developed by the automotive giants, this quality standard has extras in addition to the ISO 9000 quality standard. All of the ISO 9000 quality standard’s clauses serve as the foundation of the QS 9000 quality standard. AGS-TECH Inc. plants serving especially the automotive industry are certified to QS 9000 quality standard. THE AS 9100 STANDARD: This is a widely adopted and standardized quality management system for the aerospace industry. AS9100 replaces the earlier AS9000 and fully incorporates the entirety of the current version of ISO 9000, while adding requirements relating to quality and safety. The aerospace industry is a high risk sector, and regulatory control is needed to assure that the safety and quality of services offered in the sector are world class. Plants manufacturing our aerospace components are certified to the AS 9100 quality standard. THE ISO 13485:2003 STANDARD: This standard specifies requirements for a quality management system where an organization needs to demonstrate its ability to provide medical devices and related services that consistently meet customer and regulatory requirements applicable to medical devices and related services. The main objective of ISO 13485:2003 quality standard is to facilitate harmonized medical device regulatory requirements for quality management systems. Therefore, it includes some particular requirements for medical devices and excludes some of the requirements of ISO 9001 quality system that are not appropriate as regulatory requirements. If regulatory requirements permit exclusions of design and development controls, this can be used as a justification for their exclusion from the quality management system. AGS-TECH Inc’s medical products such as endoscopes, fiberscopes, implants are manufactured at plants that are certified to this quality management system standard. THE ISO 14000 STANDARD: This family of standards pertains to the international Environmental Management Systems. It concerns the way an organization’s activities affect the environment throughout the life of its products. These activities can range from production to disposal of the product after its useful life, and include effects on the environment including pollution, waste generation & disposal, noise, depletion of natural resources and energy. The ISO 14000 standard is related more to the environment rather than quality, but still it is one that many of AGS-TECH Inc.’s global production facilities are certified to. Indirectly though, this standard definitely can increase quality at a facility. WHAT ARE THE UL, CE, EMC, FCC and CSA CERTIFICATION LISTING MARKS ? WHO NEEDS THEM ? THE UL MARK: If a product carries the UL Mark, Underwriters Laboratories found that samples of this product met UL's safety requirements. These requirements are primarily based on UL's own published Standards for Safety. This type of Mark is seen on most appliances and computer equipment, furnaces and heaters, fuses, electrical panel boards, smoke and carbon monoxide detectors, fire extinguishers, flotation devices such as life jackets, and many other products throughout the World and especially in the USA. AGS-TECH Inc. relevant products for the US market are affixed with UL mark. In addition to manufacturing their products, as a service we can guide our customers throughout the UL qualification and marking process.Product testing can be verified through UL directories online at http://www.ul.com THE CE MARK: The European Commission allows manufacturers to circulate industrial products with CE mark freely within the internal market of the EU. AGS-TECH Inc. relevant products for the EU market are affixed with CE mark. In addition to manufacturing their products, as a service we can guide our customers throughout the CE qualification and marking process.The CE mark certifies that the products have met EU health, safety and environmental requirements that ensure consumer and workplace safety. All manufacturers in the EU as well as outside the EU must affix the CE mark to those products covered by the ''New Approach'' directives in order to market their products within the EU territory. When a product receives the CE mark, it can be marketed throughout the EU without undergoing further product modification. Most products covered by New Approach Directives can be self-certified by the manufacturer and do not require the intervention of an EU-authorized independent testing/certifying company. To self-certify, the manufacturer must assess the conformity of the products to the applicable directives and standards. While the use of EU harmonized standards is voluntary in theory, in practice the use of European standards is the best way to meet the requirements of the CE mark directives, because the standards offer specific guidelines and tests to meet safety requirements, while the directives, general in nature, do not. The manufacturer may affix the CE mark to their product after preparing a declaration of conformity, the certificate which shows the product conforms to the applicable requirements. The declaration must include the manufacturer's name and address, the product, the CE mark directives that apply to the product, e.g. the machine directive 93/37/EC or the low voltage directive 73/23/EEC, the European standards used, e.g. EN 50081-2:1993 for the EMC directive or EN 60950:1991 for the low voltage requirement for information technology. The declaration must show the signature of a company official for purposes of the company assuming liability for the safety of its product in the European market. This European standards organization has set up the Electromagnetic Compatibility Directive. According to CE, The Directive basically states that products must not emit unwanted electromagnetic pollution (interference). Because there is a certain amount of electromagnetic pollution in the environment, the Directive also states that products must be immune to a reasonable amount of interference. The Directive itself gives no guidelines on the required level of emissions or immunity that is left to the standards that are used to demonstrate compliance with the Directive. The EMC-directive (89/336/EEC) Electromagnetic Compatibility Like all other directives, this is a new-approach directive, which means that only the main requirements (essential requirements) are required. The EMC-directive mentions two ways of showing compliance to the main requirements: •Manufacturers declaration (route acc. art. 10.1) •Type testing using the TCF (route acc. to art. 10.2) The LVD-directive (73/26/EEC) Safety Like all CE-related directives, this is a new-approach directive, which means that only the main requirements (essential requirements) are required. The LVD-directive describes how to show compliance to the main requirements. THE FCC MARK: The Federal Communications Commission (FCC) is an independent United States government agency. The FCC was established by the Communications Act of 1934 and is charged with regulating interstate and international communications by radio, television, wire, satellite and cable. The FCC's jurisdiction covers the 50 states, the District of Columbia, and U.S. possessions. All devices that operate at a clock rate of 9 kHz are required to be tested to the appropriate FCC Code. AGS-TECH Inc. relevant products for the US market are affixed with FCC mark. In addition to manufacturing their electronic products, as a service we can guide our customers throughout the FCC qualification and marking process. THE CSA MARK: The Canadian Standards Association (CSA) is a nonprofit association serving business, industry, government and consumers in Canada and the global marketplace. Among many other activities, CSA develops standards that enhance public safety. As a nationally recognized testing laboratory, CSA is familiar with U.S. requirements. According to OSHA regulations, the CSA-US Mark qualifies as an alternative to the UL Mark. WHAT IS FDA LISTING ? WHICH PRODUCTS NEED FDA LISTING ? A medical device is FDA-listed if the firm that manufactures or distributes the medical device has successfully completed an online listing for the device through the FDA Unified Registration and Listing System. Medical devices that do not require FDA review before the devices are marketed are considered ''510(k) exempt.'' These medical devices are mostly low-risk, Class I devices and some Class II devices that have been determined not to require a 510(k) to provide a reasonable assurance of safety and effectiveness. Most establishments that are required to register with the FDA are also required to list the devices that are made at their facilities and the activities that are performed on those devices. If a device requires premarket approval or notification before being marketed in the U.S., then the owner/operator should also provide the FDA premarket submission number (510(k), PMA, PDP, HDE). AGS-TECH Inc. does market and sell some products such as implants that are FDA listed. In addition to manufacturing their medical products, as a service we can guide our customers throughout the FDA listing process. More information as well as most current FDA listings can be found on http://www.fda.gov WHAT ARE THE POPULAR STANDARDS AGS-TECH Inc. MANUFACTURING PLANTS COMPLY WITH ? Different customers demand from AGS-TECH Inc. compliance to different norms. Sometimes it is a matter of choice but many times the request depends on customer’s geographic location, or industry they serve, or product’s application…etc. Here are some of the most common ones: DIN STANDARDS: DIN, the German Institute for Standardization develops norms for rationalization, quality assurance, environmental protection, safety and communication in industry, technology, science, government, and the public domain. DIN norms provide companies a basis for quality, safety and minimum functionality expectations and enable you to minimize risk, improve marketability, promote interoperability. MIL STANDARDS: This is a United States defense or military norm, ''MIL-STD'', ''MIL-SPEC'', and is used to help achieve standardization objectives by the U.S. Department of Defense. Standardization is beneficial in achieving interoperability, ensuring products meet certain requirements, commonality, reliability, total cost of ownership, compatibility with logistics systems, and other defense-related objectives. It is important to note that defense norms are also used by other non-defense government organizations, technical organizations, and industry. ASME STANDARDS: American Society of Mechanical Engineers (ASME) is an engineering society, a standards organization, a research and development organization, a lobbying organization, a provider of training and education, and a nonprofit organization. Founded as an engineering society focused on mechanical engineering in North America, ASME is multidisciplinary and global. ASME is one of the oldest standards-developing organizations in the US. It produces approximately 600 codes and standards covering many technical areas, such as fasteners, plumbing fixtures, elevators, pipelines, and power plant systems and components. Many ASME standards are referred to by government agencies as tools to meet their regulatory objectives. ASME norms are therefore voluntary, unless they have been incorporated into a legally binding business contract or incorporated into regulations enforced by an authority having jurisdiction, such as a federal, state, or local government agency. ASME are used in more than 100 countries and have been translated into many languages. NEMA STANDARDS: The National Electrical Manufacturers Association (NEMA) is the association of electrical equipment and medical imaging manufacturers in the US. Its member companies manufacture products used in the generation, transmission, distribution, control, and end use of electricity. These products are used in utility, industrial, commercial, institutional, and residential applications. NEMA’s Medical Imaging & Technology Alliance division represents manufacturers of cutting-edge medical diagnostic imaging equipment including MRI, CT, X-ray, and ultrasound products. In addition to lobbying activities, NEMA publishes more than 600 standards, application guides, white and technical papers. SAE STANDARDS: SAE International, initially established as the Society of Automotive Engineers, is a U.S.-based, globally active professional association and standards organization for engineering professionals in various industries. Principal emphasis is placed on transport industries including automotive, aerospace, and commercial vehicles. SAE International coordinates the development of technical standards based on best practices. Task forces are brought together from engineering professionals of relevant fields. SAE International provides a forum for companies, government agencies, research institutions…etc. to devise technical standards and recommended practices for the design, construction, and characteristics of motor vehicle components. SAE documents do not carry any legal force, but are in some cases referenced by the U.S. National Highway Traffic Safety Administration (NHTSA) and Transport Canada in those agencies' vehicle regulations for the United States and Canada. However, outside North America, SAE documents are generally not a primary source of technical provisions in vehicle regulations. SAE publishes more than 1,600 technical standards and recommended practices for passenger cars and other road travelling vehicles and over 6,400 technical documents for the aerospace industry. JIS STANDARDS: Japanese Industrial Standards (JIS) specify the norms used for industrial activities in Japan. The standardization process is coordinated by the Japanese Industrial Standards Committee and published through the Japanese Standards Association. The Industrial Standardization Law was revised in 2004 and the ''JIS mark'' (product certification) was changed. Starting October 1, 2005, the new JIS mark has been applied upon re-certification. The use of the old mark was allowed during the three-year transition period until September 30, 2008; and every manufacturer obtaining new or renewing their certification under the authority's approval has been able to use the new JIS mark. Therefore all JIS-certified Japanese products have had the new JIS mark since October 1, 2008. BSI STANDARDS: British Standards are produced by BSI Group which is incorporated and formally designated as the National Standards Body (NSB) for the UK. The BSI Group produces British norms under the authority of the Charter, which lays down as one of the BSI's objectives to set up norms of quality for goods and services, and prepare and promote the general adoption of British Standards and schedules in connection therewith and from time to time to revise, alter and amend such standards and schedules as experience and circumstances require. The BSI Group currently has over 27,000 active standards. Products are commonly specified as meeting a particular British Standard, and generally this can be done without any certification or independent testing. The standard simply provides a shorthand way of claiming that certain specifications are met, while encouraging manufacturers to adhere to a common method for such a specification. The Kitemark can be used to indicate certification by BSI, but only where a Kitemark scheme has been set up around a particular standard. Products and services which BSI certifies as having met the requirements of specific standards within designated schemes are awarded the Kitemark. It is mainly applicable to safety and quality management. There is a common misunderstanding that Kitemarks are necessary to prove compliance with any BS standard, but in general it is neither desirable nor possible that every standard be 'policed' in this way. Because of the move on harmonization of standards in Europe, some British Standards have been gradually superseded or replaced by the relevant European norms (EN). EIA STANDARDS: The Electronic Industries Alliance was a standards and trade organization composed as an alliance of trade associations for electronics manufacturers in the United States, which developed standards to ensure the equipment of different manufacturers was compatible and interchangeable. The EIA ceased operations on February 11, 2011, but the former sectors continue to serve the constituencies of EIA. EIA designated ECA to continue to develop standards for interconnect, passive and electro-mechanical electronic components under the ANSI-designation of EIA standards. All other electronic components norms are managed by their respective sectors. ECA is expected to merge with the National Electronic Distributors Association (NEDA) to form the Electronic Components Industry Association (ECIA). However, the EIA standards brand will continue for interconnect, passive and electro-mechanical (IP&E) electronic components within ECIA. The EIA divided its activities into the following sectors: •ECA – Electronic Components, Assemblies, Equipment & Supplies Association •JEDEC – JEDEC Solid State Technology Association (formerly the Joint Electron Devices Engineering Councils) •GEIA – Now part of TechAmerica, it is the Government Electronics and Information Technology Association •TIA – Telecommunications Industry Association •CEA – Consumer Electronics Association IEC STANDARDS: The International Electrotechnical Commission (IEC) is a World organization that prepares and publishes International Standards for all electrical, electronic and related technologies. More than 10 000 experts from industry, commerce, governments, test and research labs, academia and consumer groups participate in IEC’s Standardization work. The IEC is one of three global sister organizations (they are IEC, ISO, ITU) that develop International Standards for the World. Whenever needed, the IEC cooperates with ISO (International Organization for Standardization) and ITU (International Telecommunication Union) to ensure that International Standards fit together well and complement each other. Joint committees ensure that International Standards combine all relevant knowledge of experts working in related areas. Many devices around the World that contain electronics, and use or produce electricity, rely on IEC International Standards and Conformity Assessment Systems to perform, fit and work safely together. ASTM STANDARDS: ASTM International, (formerly known as the American Society for Testing and Materials), is an international organization that develops and publishes voluntary consensus technical standards for a wide range of materials, products, systems, and services. Over 12,000 ASTM voluntary consensus standards operate globally. ASTM was established earlier than the other standards organizations. ASTM International has no role in requiring nor enforcing compliance with its standards. They may however be considered mandatory when referenced by a contract, corporation, or government entity. In the United States, ASTM standards have been widely adopted by incorporation or by reference, in many federal, state, and municipal government regulations. Other governments also have referenced ASTM in their work. Corporations doing international business frequently reference an ASTM standard. As an example, all toys sold in the United States must meet the safety requirements of ASTM F963. IEEE STANDARDS: The Institute of Electrical and Electronics Engineers Standards Association (IEEE-SA) is an organization within IEEE that develops global standards for a wide range of industries: power and energy, biomedical and health care, information technology, telecommunication and home automation, transportation, nanotechnology, information security, and others. The IEEE-SA has developed them for over a century. Experts from all over the world contribute to the development of IEEE standards. IEEE-SA is a community and not a government body. ANSI ACCREDITATION: The American National Standards Institute is a private non-profit organization that oversees the development of voluntary consensus standards for products, services, processes, systems, and personnel in the United States. The organization also coordinates U.S. standards with international standards in an effort that American products can be used worldwide. ANSI accredits standards that are developed by representatives of other standards organizations, government agencies, consumer groups, companies, …etc. These standards ensure that the characteristics and performance of products are consistent, that people use the same definitions and terms, and that products are tested the same way. ANSI also accredits organizations that carry out product or personnel certification in accordance with requirements defined in international standards. The ANSI itself does not develop standards, but oversees the development and use of standards by accrediting the procedures of standards developing organizations. ANSI accreditation signifies that the procedures used by standards developing organizations meet the Institute's requirements for openness, balance, consensus, and due process. ANSI also designates specific standards as American National Standards (ANS), when the Institute determines that the standards were developed in an environment that is equitable, accessible and responsive to the requirements of various stakeholders. Voluntary consensus standards quicken the market acceptance of products while making clear how to improve the safety of those products for the protection of consumers. There are approximately 9,500 American National Standards that carry the ANSI designation. In addition to facilitating the formation of these in the United States, ANSI promotes the use of U.S. standards internationally, advocates U.S. policy and technical positions in international and regional organizations, and encourages the adoption of international and national standards where appropriate. NIST REFERENCE: The National Institute of Standards and Technology (NIST), is a measurement standards laboratory, which is a non-regulatory agency of the United States Department of Commerce. The institute's official mission is to promote U.S. innovation and industrial competitiveness by advancing measurement science, standards, and technology in ways that enhance economic security and improve our quality of life. As part of its mission, NIST supplies industry, academia, government, and other users with over 1,300 Standard Reference Materials. These artifacts are certified as having specific characteristics or component content, used as calibration standards for measuring equipment and procedures, quality control benchmarks for industrial processes, and experimental control samples. NIST publishes the Handbook 44 that provides the specifications, tolerances, and other technical requirements for weighing and measuring devices. WHAT ARE THE OTHER TOOLS AND METHODS AGS-TECH Inc. PLANTS DEPLOY TO PROVIDE HIGHEST QUALITY ? SIX SIGMA: This is a set of statistical tools based on well known total quality management principles, to continually measure the quality of products and services in selected projects. This total quality management philosophy includes considerations such as ensuring customer satisfaction, delivering defect-free products, and understanding process capabilities. The six sigma quality management approach consists of a clear focus on defining the problem, measuring relevant quantities, analyzing, improving, and controlling processes and activities. Six Sigma quality management at many organizations simply means a measure of quality that aims for near perfection. Six Sigma is a disciplined, data-driven approach and methodology for eliminating defects and driving toward six standard deviations between the mean and the nearest specification limit in any process ranging from manufacturing to transactional and from product to service. To achieve Six Sigma quality level, a process must not produce more than 3.4 defects per million opportunities. A Six Sigma defect is defined as anything outside of customer specifications. The fundamental objective of the Six Sigma quality methodology is the implementation of a measurement-based strategy that focuses on process improvement and variation reduction. TOTAL QUALITY MANAGEMENT (TQM): This is a comprehensive and structured approach to organizational management that aims for the improvement of quality in products and services through ongoing refinements in response to continuous feedback. In a total quality management effort, all members of an organization participate in improving processes, products, services, and the culture in which they work. Total Quality Management requirements may be defined separately for a particular organization or may be defined through established standards, such as the International Organization for Standardization's ISO 9000 series. Total Quality Management can be applied to any type of organization, including production plants, schools, highway maintenance, hotel management, government institutes…etc. STATISTICAL PROCESS CONTROL (SPC): This is a powerful statistical technique used in quality control for on-line monitoring of part production and rapid identification of of the sources of quality problems. The goal of SPC is to prevent defects from occurring rather than to detect defects in production. SPC enables us to produce a million parts with only a few defective ones that fail quality inspection. LIFE CYCLE ENGINEERING / SUSTAINABLE MANUFACTURING: Life cycle engineering is concerned with environmental factors as they relate to design, optimization and technical considerations regarding each component of a product or process life cycle. It is not so much a quality concept. The goal of life cycle engineering is to consider the reuse and recycling of products from their earliest stage of design process. A related term, sustainable manufacturing emphasizes the need to conserving natural resources such as materials and energy through maintenance and reuse. As such, neither is this a quality related concept, but an environmental. ROBUSTNESS IN DESIGN, MANUFACTURING PROCESSES AND MACHINERY: Robustness is a design, a process, or a system that continues to function within acceptable parameters despite variations in its environment. Such variations are considered noise, they are difficult or impossible to control, such as variations in ambient temperature and humidity, vibrations on shop floor…etc. Robustness is related to quality, the more robust a design, process or system, the higher will be the quality of products and service. AGILE MANUFACTURING: This is a term indicating the use of the principles of lean production on a broader scale. It is ensuring flexibility (agility) in the manufacturing enterprise so that it can quickly respond to changes in product variety, demand and customer needs. It can be considered as a quality concept since it aims for customer satisfaction. Agility is achieved with machines and equipment that has built-in flexibility and reconfigurable modular structure. Other contributors to agility are advanced computer hardware & software, reduced changeover time, implementation of advanced communications systems. VALUE ADDED MANUFACTURING: Even though this is not directly related to quality management, it does have indirect effects on quality. We strive to add additional value in our production processes and services. Instead of having your products produced at many locations and suppliers, it is much more economical and better from a quality point of view to have them produced by one or only a few good suppliers. Receiving and then shipping your parts to another plant for nickel plating or anodizing will only result in increasing the chances of quality problems and add to cost. Therefore we strive to perform all the additional processes for your products, so you get a better value for your money and of course better quality due to lower risk of mistakes or damages during packaging, shipping….etc. from plant to plant. AGS-TECH Inc. offers all the quality parts, components, assemblies and finished products you need from a single source. To minimize quality risks we also do the final packaging and labeling of your products if you want it. COMPUTER INTEGRATED MANUFACTURING: You can find out more on this key concept for better quality on our dedicated page by clicking here. CONCURRENT ENGINEERING: This is a systematic approach integrating the design and manufacture of products with the view toward optimizing all elements involved in the life cycle of the products. The main goals of concurrent engineering are to minimize product design and engineering changes, and the time and costs involved in taking the product from design concept to production and introduction of the product into the marketplace. Concurrent engineering does however need top management’s support, have multifunctional and interacting work teams, need to utilize state-of-the-art technologies. Even though this approach is not directly related to quality management, it does indirectly contribute to the quality in a workplace. LEAN MANUFACTURING: You can find out more on this key concept for better quality on our dedicated page by clicking here. FLEXIBLE MANUFACTURING: You can find out more on this key concept for better quality on our dedicated page by clicking here. 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 ПРЕТХОДНА СТРАНИЦА

Composite Stereo Microscopes - Metallurgical Microscope - Fiberscope - Borescope - SADT -AGS-TECH Inc - New Mexico - USA Микроскоп, фиберскоп, борескоп, машини за мерење на видот, проектори за профили We supply MICROSCOPES, FIBERSCOPES, BORESCOPES, VISION MEASURING MACHINES, PROFILE PROJECTORS from manufacturers like SADT, SINOAGE, SINOWON for industrial applications. There are a large number of microscopes based on the physical principle used to produce an image and based on their area of application. The type of instruments we supply are OPTICAL MICROSCOPES (COMPOUND / STEREO TYPES), and METALLURGICAL MICROSCOPES. You can purchase brand new as well as refurbished or used equipment from us. Browse through our catalogs below and let us know the brand and model number and we will provide you our offers: HAIDA Color Assessment Cabinet SADT-SINOAGE Brand Metrology and Test Equipment Catalog In this catalog you will find some high quality metallurgical microscopes and inverted microscopes. SINOWON Instant Vision Measuring System SINOWON Profile Projector SINOWON Toolmakers Microscope SINOWON Vision Measuring Machine SINOWON Video Microscope We offer both FLEXIBLE and RIGID FIBERSCOPE and BORESCOPE models and they are primarily used for NONDESTRUCTIVE TESTING in confined spaces, like crevices in some concrete structures and aircraft engines. Both of these optical instruments are used for visual inspection. There are however differences between fiberscopes and borescopes: One of them is the flexibility aspect. Fiberscopes are made of flexible optic fibers and have a viewing lens attached to their head. The operator can turn the lens after insertion of the fiberscope into a crevice. This increases the operator’s view. To the contrary, borescopes are generally rigid and allow the user to view only straight ahead or at right angles. Another difference is the light source. A fiberscope does transmit light down its optical fibers to illuminate the observation area. On the other hand, a borescope has mirrors and lenses so light can be bounced from between mirrors to illuminate the observation area. Lastly, the clarity is different. Whereas fiberscopes are limited to a range of 6 to 8 inches, borescopes can provide a wider and clearer view as compared to fiberscopes. OPTICAL MICROSCOPES : These optical instruments use visible light (or UV light in the case of fluorescence microscopy) to produce an image. Optical lenses are used to refract the light. The first microscopes that were invented were optical. Optical microscopes can be further subdivided into several categories. We focus our attention to two of them: 1.) COMPOUND MICROSCOPE : These microscopes are composed of two lens systems, an objective and an ocular (eye piece). The maximum useful magnification is about 1000x. 2.) STEREO MICROSCOPE (also known as DISSECTING MICROSCOPE): These microscopes magnify to about maximum 100x and supply a 3D view of the specimen. They are useful for observing opaque objects. METALLURGICAL MICROSCOPES : Our downloadable SADT catalog with the link above does contain metallurgical and inverted metallographic microscopes. So please see our catalog for product details. In order to acquire a basic understanding about these types of microscopes, please go to our page COATING SURFACE TEST INSTRUMENTS. FIBERSCOPES : Fiberscopes incorporate fiber optic bundles, consisting of numerous fiber optic cables. Fiber optic cables are made of optically pure glass and are as thin as a human’s hair. The main components to a fiber optic cable are: Core, which is the center made of high purity glass, cladding which is he outer material surrounding the core that prevents light from leaking and finally buffer which is the protective plastic coating. Generally there are two different fiber optic bundles in a fiberscope: The first one is the illumination bundle which is designed to carry light from the source to the eyepiece and the second one is the imaging bundle designed to carry an image from the lens to the eyepiece. A typical fiberscope is made up of the following components: -Eyepiece: This is the part from where we observe the image. It magnifies the image carried by the imaging bundle for easy viewing. -Imaging Bundle: A strand of flexible glass fibers transmitting the images to the eyepiece. -Distal Lens: A combination of multiple micro lenses that take images and focus them into the small imaging bundle. -Illumination System: A Fiber optic light guide that sends light from the source to the target area (eyepiece) -Articulation System: The system providing the user the ability to control the movement of the bending section of the fiberscope that is directly attached to the distal lens. -Fiberscope Body: The control section designed to help one hand operation. -Insertion Tube: This flexible and durable tube protects the fiber optic bundle and articulation cables. -Bending Section – The most flexible part of the fiberscope connecting the insertion tube to the distal viewing section. -Distal Section: ending location for both the illumination and imaging fiber bundle. BORESCOPES / BOROSCOPES : A borescope is an optical device consisting of a rigid or flexible tube with an eyepiece on one end, and an objective lens on the other end linked together by a light transmitting optical system in between. Optical fibers surrounding the system are generally used for illuminating the object to be viewed. An internal image of the illuminated object is formed by the objective lens, magnified by the eyepiece and presented to the viewer's eye. Many modern borescopes can be fitted with imaging and video devices. Borescopes are used similar to fiberscopes for visual inspection where the area to be inspected is inaccessible by other means. Borescopes are considered nondestructive test instruments for viewing and examining defects and imperfections. The areas of application is only limited by your imagination. The term FLEXIBLE BORESCOPE is sometimes used interchangeably with the term fiberscope. One disadvantage for flexible borescopes originates from pixelation and pixel crosstalk due to the fiber image guide. Image quality varies widely among different models of flexible borescopes depending on the number of fibers and construction used in the fiber image guide. High end borescopes offer a visual grid on image captures that aids in evaluating the size of the area under inspection. For flexible borescopes, articulation mechanism components, range of articulation, field of view and angles of view of the objective lens are also important. Fiber content in the flexible relay is also critical to provide the highest possible resolution. Minimal quantity is 10,000 pixels while the best images are obtained with higher numbers of fibers in the 15,000 to 22,000 pixels range for the larger diameter borescopes. The ability to control the light at the end of the insertion tube allows the user to make adjustments that can significantly improve the clarity of images taken. On the other hand, RIGID BORESCOPES generally provide a superior image and lower cost compared to a flexible borescope. The shortcoming of rigid borescopes is the limitation that access to what is to be viewed must be in a straight line. Therefore, rigid borescopes have a limited area of application. For similar-quality instruments, the largest rigid borescope that will fit the hole gives the best image. A VIDEO BORESCOPE is similar to the flexible borescope but uses a miniature video camera at the end of the flexible tube. The end of the insertion tube includes a light which makes it possible to capture video or still images deep within the area of investigation. The ability of video borescopes to capture video and still images for later inspection is very useful. Viewing position can be changed via a joystick control and displayed on the screen mounted on its handle. Because the complex optical waveguide is replaced with an inexpensive electrical cable, video borescopes can be much less costly and potentially offer better resolution. Some borescopes offer USB cable connection. For details and other similar equipment, please visit our equipment website: http://www.sourceindustrialsupply.com КЛИКНЕТЕ Услуга за пронаоѓање на производи-локатор ПРЕТХОДНА СТРАНИЦА

Non-Conventional Fabrication, ECM, EDM, PMC, Waterjet Machining, Laser, Plasma, EBM Machining, Ultrasonic Machining, Soldering, Welding, Brazing,Special Bonding Неконвенционална изработка Прочитај повеќе ECM обработка, електрохемиска обработка, мелење Прочитај повеќе EDM обработка, глодање и мелење со електрично празнење Прочитај повеќе Хемиска обработка и фотохемиско бланирање Прочитај повеќе Воден млаз обработка и абразивна млазница и абразивна обработка и сечење Прочитај повеќе Ласерска обработка и сечење и LBM Прочитај повеќе Плазма обработка и сечење Прочитај повеќе Ултразвучна обработка и ротациона ултразвучна обработка и мелење со ултразвучно влијание Прочитај повеќе EBM Machining & Electron Beam Machining Прочитај повеќе Лемење и лемење и заварување Прочитај повеќе Adhesive Bonding & Sealing & Custom Mechanical Fastening and Assembly Among the major NON-CONVENTIONAL FABRICATION techniques we offer are Electrochemical Fabrication (also called Electrochemical Machining or ECM), Electrical Discharge Machining or EDM, Water Jet Cutting, Abrasive Water Jet Cutting (WJ, AWJ), Laser Beam Machining (LBM), Electron Beam Machining (EBM), Ultrasonic Machining (USM), Plasma Machining, Photochemical Machining (abbreviated as PCM or also called Chemical Etching, Metal Etching, Chemical Milling, Chemical Machining), Soldering, Brazing, Welding, Specialty Bonding and Pickling. Sometimes, it is easier and more economical to get the work done by some chemicals, pressurized water jet or even light rather than using traditional techniques such as machining and stamping. On the submenu pages, you can find a summary of each of these alternative non-conventional fabrication techniques we are offering you. Non-conventional fabrication is also referred to as non-traditional fabrication. What distinguishes convention and non-conventional fabrication techniques ? – Generally speaking, conventional fabrication involves changing the shape of a work piece using an implement made of a harder material. Machining hard materials using conventional methods may require significant time and energy and result in high costs. In addition, conventional machining may lead to excessive tool wear and loss of quality in the product owing to induced residual stresses during manufacture. Therefore, especially for hard alloys, non-conventional fabrication techniques may be better alternatives. Whereas conventional fabrication processes generally use mechanical energy (motion), non-conventional fabrication processes utilize other forms of energy. Main forms of energy non-conventional fabrication processes use are: Thermal, Chemical and Electrical Energy. There can be a large number of advantages of non-conventional fabrication techniques over conventional methods. Just to name a few, non-conventional fabrication may involve quieter operation and no sound pollution, such as is the case with Chemical Machining. In non-conventional fabrication, material removal may occur with or without chip formation. For example, in Electrochemical Machining, material removal occurs due to electrochemical dissolution at atomic levels. Non-conventional fabrication may involve lower waste of material due to low or no wear as compared to conventional fabrication. On the other hand, non-conventional fabrication methods do have some disadvantages such as higher capital costs and the need for skilled operators. Also, non-conventional fabrication methods are not suitable for every type of material economically. Here is a downloadable guide comparing conventional and non-conventional fabrication methods: - A Brief Comparison of Conventional and Non-Conventional Fabrication Methods Since we are the World’s most diverse Global Custom Manufacturer, Integrator, Consolidator and Outsourcing Partner; we see it as our duty to determine technically the most suitable and economically the most feasible fabrication technique for your needs. Available techniques involve our non-conventional fabrication methods among others. In order to contract us to manufacture your products, you do not need to be an expert in non-conventional fabrication methods or any other production techniques. We are here to assist and guide you in the right direction. All you need is to contact us and provide as much information as possible about your production needs. We will review your input and determine whether conventional or non-conventional fabrication techniques will be the best fit for your products. We will take into consideration many factors such as lead times, number of parts to be produced, costs, dimensional specifications of your parts and products, material properties and requirements and determine which non-conventional or conventional fabrication technique or techniques will be the best fit. For almost all fabrication techniques, whether it be conventional or non-conventional, we do use CAD/CAM and automated CNC machines as well as manual machines. Sometimes manual machinery is more suitable and practical while for high volume orders automated CNCs are deployed exclusively. We have prepared a brochure below which you can download as a reference source for frequently used mechanical engineering terms: - Download brochure for Common Mechanical Engineering Terms used by Designers and Engineers If you are mostly interested in our engineering and research & development capabilities instead of manufacturing capabilities, then we invite you to visit our engineering website http://www.ags-engineering.com (On our engineering website you can find details about our engineering services such as design, product development, consulting…etc.) КЛИКНЕТЕ Услуга за пронаоѓање на производи-локатор ПРЕТХОДНА СТРАНИЦА

AGS-TECH Inc Customer References - We have many loyal customers satisfied with our global custom manufacturing & engineering integration services Референци на клиентите AGS-TECH, Inc. опслужува домашни и меѓународни клиенти речиси две децении. Многу од нашите клиенти долги години ги доставуваат производствените операции, компоненти, делови, склопови и готови производи од нас. Контактирајте не за референци на клиентите. PLEASE CLICK HERE TO READ TESTIMONIALS AND FEEDBACK FROM SOME OF OUR CUSTOMERS ПРЕТХОДНА СТРАНИЦА

Custom Manufactured Parts, Assemblies, Plastic Molds, Casting, CNC Machining, Extrusion, Metal Forging, Spring Manufacturing, Products Assembly, PCBA, PCB AGS-TECH, Inc. е ваш Глобален прилагоден производител, интегратор, консолидатор, аутсорсинг партнер. Ние сме вашиот едношалтерски извор за производство, изработка, инженерство, консолидација, аутсорсинг. Прилагодено произведени делови и склопови Дознајте повеќе Производство на машински елементи Дознајте повеќе Сврзувачки елементи, Производство на хардвер за местење Дознајте повеќе Производство на алатки за сечење, дупчење, обликување Дознајте повеќе Пневматика, хидраулика, вакуумски производи Неконвенционална изработка Дознајте повеќе Learn More Производство на вонредни производи Дознајте повеќе Производство на нано, микро, мезоскали Learn More Производство на електрична и електроника Дознајте повеќе Производство на оптички, оптички влакна, оптоелектроника Дознајте повеќе Инженерска интеграција Производство на сложувалки, уреди, алатки Learn More Дознајте повеќе Производство на машини и опрема Дознајте повеќе Индустриска опрема за тестирање Дознајте повеќе 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.

Industrial Processing Machines and Equipment Manufacturing, Custom Manufacture of Machines, Motion Control, Power & Control, Dipping and Dispensing, Pick and Place, Controlled Shaking, Controlled Rotation, Slitting and Cutting, Oiling, Surface Finishing, Painting, Coating, Controlled Grinding and Chopping, Automated Inspection, Special Purpose Machines Automation, One-Off Machines, Smart Factory Производство на машини и опрема за индустриска обработка We supply our customers custom manufactured and off-shelf industrial processing machines and equipment. - Brand new custom manufactured industrial machine or equipment made to your needs and specifications. - Brand new off-shelf industrial machines and equipment - Refurbished, rebuilt or upgraded industrial machines and equipment Some types of machines and equipment we are experienced in include the following generic groups: - Robotic Machines, Robots - High Vacuum Equipment - Equipment for clean rooms and critical environments. - Thermal Processing Machines and Equipment - Continuous Process Machines and Equipment - Web Forming, Handling & Converting Some of the type of automation we can incorporate in your custom made equipment include: - Motion Control - Power & Control - Dipping and Dispensing - Pick and Place - Controlled Shaking - Controlled Rotation - Slitting and Cutting - Oiling, Surface Finishing, Painting, Coating - Controlled Grinding and Chopping - Automated Inspection - Special Purpose Machines Automation - One-Off Machines - Smart Factory - PLC Machines and equipment we build or supply include the following industrial sectors: - Food and Beverage - Heavy Industry - Biomedical - Pharmaceutical - Chemical Industry - Construction - Glass and Ceramics Industry - High-Tech Industries - Consumer Goods Industry - Textile Industry Some specific machines and equipment built, rebuilt or upgraded include: - Pipe bending machines - Press room equipment such as sheet metal bending and forming machines - Cable and wire winding machines, coil processing - Hydraulic and pneumatic lifting, turning systems - Single and double leg crushers - Labeling, printing, packaging machines - Metal forming machinery - Custom part handling machinery - Slitting, trimming, cutting machines - Shape correction and leveling machinery - Grinding machines - Chopping Machinery - Ovens, dryers, roasters - Food processing machines - Sizing and separation machines - Industrial filling machine solutions - Horizontal, incline, belt, bucket conveyors - Oiling, finishing, painting, coating machines - Surface treatment equipment - Pollution control equipment - Inspection and quality control equipment - 2D and 3D vision systems Download brochure for our CUSTOM MACHINE AND EQUIPMENT MANUFACTURING D owload brochure for our DESIGN PARTNERSHIP PROGRAM Below, you can click and download brochures of some high quality products we use in manufacturing and integration of your custom industrial machines and equipment . If you wish, you may also procure these products from us for below list-prices and build your own systems: 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) Brazing Machines (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 Collaborative Robots Customized Agricultural Robots Customized Commercial Places Robots Customized Health Care and Hospital Robots Customized Warehousing Robots Customized Robots for a Variety of Applications Fixed Industrial Scanners (We private label these with your brand name and logo if you wish) Hikrobot Machine Vision Products Hikrobot Smart Machine Vision Products Hikrobot Machine Vision Standard Products Hikvision Logistic Vision Solutions Hose Crimping Machines (We private label these with your brand name and logo if you wish) Hose-Cut-Off-Skive-Machine (We private label these with your brand name and logo if you wish) Hose Endforming Machines (We private label these with your brand name and logo if you wish) 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) Mobile Computers for Enterprises (We private label these with your brand name and logo if you wish) Power Tools for Every Industry (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) Process Automation Solutions (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) Robot Palletizing Workstation Robotic Laser Welding Workstation Robotics Product Brochure Robotics Workstations Selection Guide of Industrial Robot Platforms Servo C-Frame Utility Press (We private label these with your brand name and logo if you wish) Tube Bending Machines (We private label these with your brand name and logo if you wish) Welding Robots Brochure You may also find our following page useful: Jigs, Fixtures, Tools, Workholding Solutions,Mold Components Manufacturing КЛИКНЕТЕ Услуга за пронаоѓање на производи-локатор PREVIOUS PAGE

Casting and Machined Parts, CNC Manufacturing, Milling, Turning, Swiss Type Machining, Die Casting, Investment Casting, Lost Foam Cast Parts from AGS-TECH Inc. Лиење и обработка Our custom casting and machining techniques are expendable and non-expendable castings, ferrous and nonferrous casting, sand, die, centrifugal, continuous, ceramic mold, investment, lost foam, near-net-shape, permanent mold (gravity die casting), plaster mold (plaster casting) and shell castings, machined parts produced by milling and turning using conventional as well as CNC equipment, swiss type machining for high throughput inexpensive small precision parts, screw machining for fasteners, non-conventional machining. Please keep in mind that besides metals and metal alloys, we machine ceramic, glass and plastic components as well in some cases when manufacturing a mould is not appealing or not the option. Machining of polymer materials requires the specialized experience we have because of the challenge plastics and rubber presents due to their softness, non-rigidity...etc. For machining of ceramic and glass, please see our page on Non-Conventional Fabrication. AGS-TECH Inc. manufactures and supplies both lightweight and heavy castings. We have been supplying metal castings and machined parts for boilers, heat exchangers, automobiles, micromotors, wind turbines, food packaging equipment and more. We recommend that you click here to DOWNLOAD our Schematic Illustrations of Machining and Casting Processes by AGS-TECH Inc. This will help you better understand the information we are providing you below. Let’s look at some of the various techniques we offer in detail: • EXPENDABLE MOLD CASTING : This broad category refers to methods that involve temporary and non-reusable molds. Examples are sand, plaster, shell, investment (also called lost-wax) and plaster casting. • SAND CASTING : A process where sand is used as the mold material. A very old method and still very popular to the extent that the majority of metal castings produced are made by this technique . Low cost even at low quantity production. Suitable for small and large parts manufacturing. The technique can be used to manufacture parts within days or weeks with very little investment. The moist sand is bonded together using clay, binders or special oils. Sand is generally contained in mold boxes and cavity & gate system are created by compacting the sand around models. The processes are: 1.) Placing of the model in sand to make the mold 2.) Incorporation of model and sand in a gating system 3.) Removal of model 4.) Filling of mold cavity with molten metal 5.) Cooling of the metal 6.) Breaking the sand mold and removal of the casting • PLASTER MOLD CASTING : Similar to sand casting, and instead of sand, plaster of paris is being used as the mold material. Short production lead times like sand casting and inexpensive. Good dimensional tolerances and surface finish. Its major disadvantage is that it can only be used with low melting point metals like aluminum and zinc. • SHELL MOLD CASTING : Also similar to sand casting. Mold cavity obtained by hardened shell of sand and thermosetting resin binder instead of flask filled with sand as in sand casting process. Almost any metal suitable to be cast by sand can be cast by shell molding. The process can be summarized as: 1.) Manufacturing of the shell mold. Sand used is of a much smaller grain size when compared to sand used in sand casting. The fine sand is mixed with thermosetting resin. The metal pattern is coated with a parting agent to make removal of the shell easier. Thereafter the metal pattern is heated and the sand mixture is pored or blown onto the hot casting pattern. A thin shell forms on the surface of the pattern. The thickness of this shell can be adjusted by varying the length of time the sand resin mixture is in contact with the metal pattern. The loose sand is then removed with the shell covered pattern remaining. 2.) Next, the shell and pattern are heated in an oven so that the shell hardens. After hardening is complete, the shell is ejected from pattern using pins built into the pattern. 3.) Two such shells are assembled together by gluing or clamping and make up the complete mold. Now the shell mold is inserted into a container in which it is supported by sand or metal shot during the casting process. 4.) Now the hot metal can be poured into the shell mold. Advantages of shell casting are products with very good surface finish, possibility of manufacturing complex parts with high dimensional accuracy, process easy to automate, economical for large volume production. Disadvantages are the molds necessitate good ventilation because of gases that are created when molten metal contacts the binder chemical, the thermosetting resins and metal patterns are expensive. Due to the cost of metal patterns, the technique may not suit well for low quantity production runs. • INVESTMENT CASTING ( also known as LOST-WAX CASTING ): Also a very old technique and suitable for manufacturing quality parts with high accuracy, repeatability, versatility and integrity from many metals, refractory materials and special high performance alloys. Small as well as large sized parts can be produced. An expensive process when compared to some of the other methods, but major advantage is the possibility to produce parts with near net shape, intricate contours and details. So the cost is somewhat offset by the elimination of rework and machining in some cases. Even though there can be variations, here is a summary of the general investment casting process: 1.) Creation of original master pattern from wax or plastic. Each casting needs one pattern as these are destroyed in the process. Mold from which patterns are manufactured is also needed and most of the time the mold is cast or machined. Because the mold does not need to be opened, complex castings can be achieved, many wax patterns can be connected like the branches of a tree and poured together, thus enabling production of multiple parts from a single pouring of the metal or metal alloy. 2.) Next, the pattern is dipped or poured over with a refractory slurry composed of very fine grained silica, water, binders. This results in a ceramic layer over the surface of the pattern. The refractory coat on pattern is left to dry and harden. This step is where the name investment casting comes from: Refractory slurry is invested over the wax pattern. 3.) At this step, the hardened ceramic mould is turned upside down and heated so that the wax melts and pours out of the mould. A cavity is left behind for the metal casting. 4.) After the wax is out, the ceramic mold is heated to even a higher temperature which results in strengthening of the mold. 5.) Metal casting is poured into the hot mold filling all intricate sections. 6.) Casting is allowed to solidify 7.) Finally the ceramic mould is broken and manufactured parts are cut from the tree. Here is a link to Investment Casting Plant Brochure • EVAPORATIVE PATTERN CASTING : The process uses a pattern made from a material such as polystyrene foam that will evaporate when hot molten metal is poured into the mold. There are two types of this process: LOST FOAM CASTING which uses unbonded sand and FULL MOLD CASTING which uses bonded sand. Here are the general process steps: 1.) Manufacture the pattern from a material such as polystyrene. When large quantities will be manufactured, the pattern is molded. If part has a complex shape, several sections of such foam material may need to be adhered together to form the pattern. We often coat the pattern with a refractory compound to create a good surface finish on the casting. 2.) The pattern is then put into molding sand. 3.) The molten metal is poured into the mould, evaporating the foam pattern, i.e. polystyrene in most cases as it flows through the mold cavity. 4.) The molten metal is left in the sand mold to harden. 5.) After it is hardened, we remove the casting. In some cases, the product we manufacture requires a core within the pattern. In evaporative casting, there is no need to place and secure a core in the mold cavity. The technique is suitable for manufacturing of very complex geometries, it can be easily automated for high volume production, and there are no parting lines in the cast part. The basic process is simple and economical to implement. For large volume production, since a die or mold is needed to produce the patterns from polystyrene, this may be somewhat costly. • NON-EXPANDABLE MOLD CASTING : This broad category refers to methods where the mold does not need to be reformed after each production cycle. Examples are permanent, die, continuous and centrifugal casting. Repeatability is obtained and parts can be characterized as NEAR NET SHAPE. • PERMANENT MOLD CASTING : Reusable molds made from metal are used for multiple castings. A permanent mold can generally be used for tens of thousands of times before it wears out. Gravity, gass pressure or vacuum are generally used to fill the mould. Molds (also called die) is generally made of iron, steel, ceramic or other metals. The general process is: 1.) Machine and create the mould. It is common to machine the mold out of two metal blocks that fit together and can be opened and closed. Both the part features as well as the gating system is generally machined into the casting mould. 2.) The internal mold surfaces are coated with a slurry incorporating refractory materials. This helps to control heat flow and acts as a lubricant for easy removal of the cast part. 3.) Next, the permanent mold halves are closed and the mold is heated. 4.) Molten metal is poured into mould and let still for solidification. 5.) Before much cooling occurs, we remove the part from permanent mold using ejectors when mold halves are opened. We frequently use permanent mold casting for low melting point metals such as zinc and aluminum. For steel castings, we use graphite as mold material. We sometimes obtain complex geometries using cores within permanent molds. Advantages of this technique are castings with good mechanical properties obtained by rapid cooling, uniformity in properties, good accuracy and surface finish, low reject rates, possibility of automating the process and producing high volumes economically. Disadvantages are high initial setup costs which make it unsuitable for low volume operations, and limitations on the size of the parts manufactured. • DIE CASTING : A die is machined and molten metal is pushed under high pressure into mold cavities. Both nonferrous as well as ferrous metal die castings are possible. The process is suitable for high quantity production runs of small to medium sized parts with details, extremely thin walls, dimensional consistency and good surface finish. AGS-TECH Inc. is capable to manufacture wall thicknesses as small as 0.5 mm using this technique. Like in permanent mold casting, the mold needs to consist of two halves that can open and close for removal of part produced. A die casting mold may have multiple cavities to enable production of multiple castings with each cycle. Die casting molds are very heavy and much larger than the parts they produce, therefore also expensive. We repair and replace worn out dies free of charge for our customers as long as they reorder their parts from us. Our dies have long lifetimes in the several hundred thousand cycles range. Here are the basic simplified process steps: 1.) Production of the mold generally from steel 2.) Mold installed on die casting machine 3.) The piston forces molten metal to flow in the die cavities filling out the intricate features and thin walls 4.) After filling the mold with the molten metal, the casting is let hardened under pressure 5.) Mold is opened and casting removed with the help of ejector pins. 6.) Now the empty die are lubricated again and are clamped for the next cycle. In die casting, we frequently use insert molding where we incorporate an additional part into the mold and cast the metal around it. After solidification, these parts become part of the cast product. Advantages of die casting are good mechanical properties of the parts, possibility of intricate features, fine details and good surface finish, high production rates, easy automation. Disadvantages are: Not very suitable for low volume because of high die and equipment cost, limitations in shapes that can be cast, small round marks on cast parts resulting from contact of ejector pins, thin flash of metal squeezed out at the parting line, need for vents along the parting line between the die, necessity to keep mold temperatures low using water circulation. • CENTRIFUGAL CASTING : Molten metal is poured into the center of the rotating mold at the axis of rotation. Centrifugal forces throw the metal towards the periphery and it is let to solidify as the mold keeps rotating. Both horizontal and vertical axis rotations can be used. Parts with round inner surfaces as well as other non-round shapes can be cast. The process can be summarized as: 1.) Molten metal is poured into centrifugal mould. The metal is then forced to the outer walls due to spinning of the mold. 2.) As the mold rotates, the metal casting hardens Centrifugal casting is a suitable technique for production of hollow cylindirical parts like pipes, no need for sprues, risers and gating elements, good surface finish and detailed features, no shrinkage issues, possibility to produce long pipes with very large diameters, high rate production capability. • CONTINUOUS CASTING ( STRAND CASTING ) : Used to cast a continuous length of metal. Basically the molten metal is cast into two dimensional profile of the mold but its length is indeterminate. New molten metal is constantly fed into the mould as the casting travels downward with its length increasing with time. Metals such as copper, steel, aluminum are cast into long strands using continuous casting process. The process may have various configurations but the common one can be simplified as: 1.) Molten metal is poured into a container located high above the mold at well calculated amounts and flow rates and flows through the water cooled mold. The metal casting poured into the mould solidifies to a starter bar placed at the bottom of the mold. This starter bar gives the rollers something to grab onto initially. 2.) The long metal strand is carried by rollers at a constant speed. The rollers also change the direction of the flow of metal strand from vertical to horizontal. 3.) After the continuous casting has travelled a certain horizontal distance, a torch or saw that moves with the casting quickly cuts it to desired lengths. Continuous casting process can be integrated with ROLLING PROCESS, where the continuously cast metal can be fed directly into a rolling mill to produce I-Beams, T-Beams….etc. Continuous casting produces uniform properties throughout the product, it has a high solidification rate, reduces cost due to very low loss of material, offers a process where loading of metal, pouring, solidification, cutting and casting removal all take place in a continuous operation and thus resulting in high productivity rate and high quality. A major consideration is however the high initial investment, setup costs and space requirements. • MACHINING SERVICES : We offer three, four and five - axis machining. The type of machining processes we use are TURNING, MILLING, DRILLING, BORING, BROACHING, PLANING, SAWING, GRINDING, LAPPING, POLISHING and NON-TRADITIONAL MACHINING which is further elaborated under a different menu of our website. For most of our manufacturing, we use CNC machines. However for some operations conventional techniques are a better fit and therefore we rely on them as well. Our machining capabilities reach the highest level possible and some most demanding parts are manufactured at an AS9100 certified plant. Jet engine blades require highly specialized manufacturing experience and the right equipment. Aerospace industry has very strict standards. Some components with complex geometrical structures are most easily manufactured by five axis machining, which is found only in some machining plants including ours. Our aerospace certified plant has the necessary experience complying to extensive documentation requirement of the aerospace industry. In TURNING operations, a workpiece is rotated and moved against a cutting tool. For this process a machine called lathe is being used. In MILLING, a machine called milling machine has a rotating tool to bring cutting edges to bear against a workpiece. DRILLING operations involve a rotating cutter with cutting edges that produces holes upon contact with the workpiece. Drill presses, lathes or mills are generally used. In BORING operations a tool with a single bent pointed tip is moved into a rough hole in a spinning workpiece to slightly enlarge the hole and improve accuracy. It is used for fine finishing purposes. BROACHING involves a toothed tool to remove material from a workpiece in one pass of the broach (toothed tool). In linear broaching, the broach runs linearly against a surface of the workpiece to effect the cut, whereas in rotary broaching, the broach is rotated and pressed into the workpiece to cut an axis symmetric shape. SWISS TYPE MACHINING is one of our valuable techniques we use for high volume manufacturing of small high precision parts. Using Swiss-type lathe we turn small, complex, precision parts inexpensively. Unlike conventional lathes where the workpiece is kept stationary and tool moving, in Swiss-type turning centers, the workpiece is allowed to move in the Z-axis and the tool is stationary. In Swiss-type machining, the bar stock is held in the machine and advanced through a guide bushing in the z-axis, only exposing the portion to be machined. This way a tight grip is ensured and accuracy is very high. Availability of live tools provide the opportunity to mill and drill as the material advances from the guide bushing. The Y-axis of the Swiss-type equipment provides full milling capabilities and saves great amount of time in manufacturing. Furthermore, our machines have drills and boring tools that operate on the part when it is held in the sub spindle. Our Swiss-Type machining capability gives us a fully automated complete machining opportunity in a single operation. Machining is one of the largest segments of AGS-TECH Inc. business. We either use it as a primary operation or a secondary operation after casting or extruding a part so that all drawing specifications are met. • SURFACE FINISHING SERVICES : We offer a vast variety of surface treatments and surface finishing 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 coating for drilling and cutting tools. • PRODUCT MARKING & LABELING SERVICES : Many of our customers require marking and labeling, laser marking, engraving on metal parts. If you have any such need, let us discuss which option will be the best for you. Here are some of commonly used metal cast 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 11 Series Die-cast Aluminium Boxes from AGS-Electronics КЛИКНЕТЕ Услуга за пронаоѓање на производи-локатор ПРЕТХОДНА СТРАНИЦА