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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

Rapid Electronic Prototyping, Custom Robot Assembly, Optomechanical Prototype Manufacturing, AGS-TECH Електронско прототипирање Прототип на електронски робот со блиски инфрацрвени детектори, стадиум на ротација и навалена глава на врвот Брзо електронско прототипирање Четирислојна ПХБ со RO4003C на врвот на слој потопено злато Прототип на ПХБ за соларен проект Дизајн и распоред на прототип со два слоја PCBA Оптоелектронски прототип на робот Услуги за прототипирање на PCBA Повеќеслојна плоча PCBA Прототипирање Прототип на склопување на табла со печатено коло Прототип на собранието на електронски жици Прилагодено прототипирање на засилувач Прототипирање на електронски засилувач ПРЕТХОДНА СТРАНИЦА

Electronic Testers - Electrical Test Equipment - Electrical Properties Testing - Oscilloscope - Signal Generator - Function Generator - Pulse Generator - Frequency Synthesizer - Multimeter Електрична и електронска опрема за тестирање With the term ELECTRONIC TESTER we refer to test equipment that is used primarily for testing, inspection and analysis of electrical and electronic components and systems. We offer the most popular ones in the industry: POWER SUPPLIES & SIGNAL GENERATING DEVICES: POWER SUPPLY, SIGNAL GENERATOR, FREQUENCY SYNTHESIZER, FUNCTION GENERATOR, DIGITAL PATTERN GENERATOR, PULSE GENERATOR, SIGNAL INJECTOR METERS: DIGITAL MULTIMETERS, LCR METER, EMF METER, CAPACITANCE METER, BRIDGE INSTRUMENT, CLAMP METER, GAUSSMETER / TESLAMETER/ MAGNETOMETER, GROUND RESISTANCE METER ANALYZERS: OSCILLOSCOPES, LOGIC ANALYZER, SPECTRUM ANALYZER, PROTOCOL ANALYZER, VECTOR SIGNAL ANALYZER, TIME-DOMAIN REFLECTOMETER, SEMICONDUCTOR CURVE TRACER, NETWORK ANALYZER, PHASE ROTATION TESTER, FREQUENCY COUNTER You can purchase brand new, refurbished or used test equipment from us at the most competitive discounted prices. Simply choose the product from the downloadable catalogs and let us know the product name, product code and relevant information and we will send you our quote. Download by clicking on highlighted text: ANRITSU Electronic Measuring Instruments FLUKE Test Tools Catalog KEYSIGHT Basic Automotive Test Products KEYSIGHT Basic Instruments KEYSIGHT Bench and Power Products KEYSIGHT Network Analyzer Products KEYSIGHT Signal Generation Solutions KEYSIGHT Smart Bench Essentials Series Products KEYSIGHT High-Volume Traffic Generator Products KEYSIGHT Layer 4-7 Network Test Products KEYSIGHT Layer 2-3 Network Test Products KEYSIGHT Distribution Products Catalog MEGGER Low Voltage Test Tools Catalog MICROWAVE Flexible Cable Assembly MICROWAVE and MILIMETER WAVE Test Accessories Brochure (Cable assemblies, VNA Test Assemblies, Mechanical Calibration Kits, RF Coaxial Adapters, Test Port Adapters, DC Blocks, NMD Connectors....etc.) Private Label Hand Tools for Every Industry (This catalog contains a few electrical & electronic test instruments. We can private label these hand tools if you wish. In other words, we can put your company name, brand and label on them. This way you can promote your brand by reselling these to your customers.) ROHDE SCHWARZ Benchtop Power Supplies Ideal for labs and system racks, galvanic isolation, floating channels, constant voltage or current modes, protection functions, parallel and serial operation, low ripple/noise, remote sensing option ROHDE SCHWARZ Test Equipment Catalog (Oscilloscopes, Power Supplies, Signal Generators, Handheld Analyzers, Spectrum Analyzers, Vector Network Analyzers, Meters & Counters) TEKTRONIX Product Catalog for Test and Measurement Solutions VANDAL-PROOF IP65/IP67/IP68 Keyboards, Keypads, Pointing Devices, ATM Pinpads, Medical & Military Keyboards and other similar Rugged Computer Peripherals For details and other similar equipment, please visit our equipment website: http://www.sourceindustrialsupply.com Let us briefly go over some of these equipment in everyday use throughout the industry: The electrical power supplies we supply for metrology purposes are discrete, benchtop and stand-alone devices. The ADJUSTABLE REGULATED ELECTRICAL POWER SUPPLIES are some of the most popular ones, because their output values can be adjusted and their output voltage or current is maintained constant even if there are variations in input voltage or load current. ISOLATED POWER SUPPLIES have power outputs that are electrically independent of their power inputs. Depending on their power conversion method, there are LINEAR and SWITCHING POWER SUPPLIES. The linear power supplies process the input power directly with all their active power conversion components working in the linear regions, whereas the switching power supplies have components working predominantly in non-linear modes (such as transistors) and convert power to AC or DC pulses before processing. Switching power supplies are generally more efficient than linear supplies because they lose less power due to shorter times their components spend in the linear operating regions. Depending on application, a DC or AC power is used. Other popular devices are PROGRAMMABLE POWER SUPPLIES, where voltage, current or frequency can be remotely controlled through an analog input or digital interface such as an RS232 or GPIB. Many of them have an integral microcomputer to monitor and control the operations. Such instruments are essential for automated testing purposes. Some electronic power supplies use current limiting instead of cutting off power when overloaded. Electronic limiting is commonly used on lab bench type instruments. SIGNAL GENERATORS are another widely used instruments in lab and industry, generating repeating or non-repeating analog or digital signals. Alternatively they are also called FUNCTION GENERATORS, DIGITAL PATTERN GENERATORS or FREQUENCY GENERATORS. Function generators generate simple repetitive waveforms such as sine waves, step pulses, square & triangular and arbitrary waveforms. With Arbitrary waveform generators the user can generate arbitrary waveforms, within published limits of frequency range, accuracy, and output level. Unlike function generators, which are limited to a simple set of waveforms, an arbitrary waveform generator allows the user to specify a source waveform in a variety of different ways. RF and MICROWAVE SIGNAL GENERATORS are used for testing components, receivers and systems in applications such as cellular communications, WiFi, GPS, broadcasting, satellite communications and radars. RF signal generators generally work between a few kHz to 6 GHz, while microwave signal generators operate within a much wider frequency range, from less than 1 MHz to at least 20 GHz and even up to hundreds of GHz ranges using special hardware. RF and microwave signal generators can be classified further as analog or vector signal generators. AUDIO-FREQUENCY SIGNAL GENERATORS generate signals in the audio-frequency range and above. They have electronic lab applications checking of the frequency response of audio equipment. VECTOR SIGNAL GENERATORS, sometimes also referred to as DIGITAL SIGNAL GENERATORS are capable of generating digitally-modulated radio signals. Vector signal generators can generate signals based on industry standards such as GSM, W-CDMA (UMTS) and Wi-Fi (IEEE 802.11). LOGIC SIGNAL GENERATORS are also called DIGITAL PATTERN GENERATOR. These generators produce logic types of signals, that is logic 1s and 0s in the form of conventional voltage levels. Logic signal generators are used as stimulus sources for functional validation & testing of digital integrated circuits and embedded systems. The devices mentioned above are for general-purpose use. There are however many other signal generators designed for custom specific applications. A SIGNAL INJECTOR is a very useful and quick troubleshooting tool for signal tracing in a circuit. Technicians can determine the faulty stage of a device such as a radio receiver very quickly. The signal injector can be applied to the speaker output, and if the signal is audible one can move to the preceding stage of the circuit. In this case an audio amplifier, and if the injected signal is heard again one can move the signal injection up the stages of the circuit until the signal is no longer audible. This will serve the purpose of locating the location of the problem. A MULTIMETER is an electronic measuring instrument combining several measurement functions in one unit. Generally, multimeters measure voltage, current, and resistance. Both digital and analog version are available. We offer portable hand-held multimeter units as well as laboratory-grade models with certified calibration. Modern multimeters can measure many parameters such as: Voltage (both AC / DC), in volts, Current (both AC / DC), in amperes, Resistance in ohms. Additionally, some multimeters measure: Capacitance in farads, Conductance in siemens, Decibels, Duty cycle as a percentage, Frequency in hertz, Inductance in henries, Temperature in degrees Celsius or Fahrenheit, using a temperature test probe. Some multimeters also include: Continuity tester; sounds when a circuit conducts, Diodes (measuring forward drop of diode junctions), Transistors (measuring current gain and other parameters), battery checking function, light level measuring function, acidity & Alkalinity (pH) measuring function and relative humidity measuring function. Modern multimeters are often digital. Modern digital multimeters often have an embedded computer to make them very powerful tools in metrology and testing. They include features such as:: •Auto-ranging, which selects the correct range for the quantity under test so that the most significant digits are shown. •Auto-polarity for direct-current readings, shows if the applied voltage is positive or negative. •Sample and hold, which will latch the most recent reading for examination after the instrument is removed from the circuit under test. •Current-limited tests for voltage drop across semiconductor junctions. Even though not a replacement for a transistor tester, this feature of digital multimeters facilitates testing diodes and transistors. •A bar graph representation of the quantity under test for better visualization of fast changes in measured values. •A low-bandwidth oscilloscope. •Automotive circuit testers with tests for automotive timing and dwell signals. •Data acquisition feature to record maximum and minimum readings over a given period, and to take a number of samples at fixed intervals. •A combined LCR meter. Some multimeters can be interfaced with computers, while some can store measurements and upload them to a computer. Yet another very useful tool, an LCR METER is a metrology instrument for measuring the inductance (L), capacitance (C), and resistance (R) of a component. The impedance is measured internally and converted for display to the corresponding capacitance or inductance value. Readings will be reasonably accurate if the capacitor or inductor under test does not have a significant resistive component of impedance. Advanced LCR meters measure true inductance and capacitance, and also the equivalent series resistance of capacitors and the Q factor of inductive components. The device under test is subjected to an AC voltage source and the meter measures the voltage across and the current through the tested device. From the ratio of voltage to current the meter can determine the impedance. The phase angle between the voltage and current is also measured in some instruments. In combination with the impedance, the equivalent capacitance or inductance, and resistance, of the device tested can be calculated and displayed. LCR meters have selectable test frequencies of 100 Hz, 120 Hz, 1 kHz, 10 kHz, and 100 kHz. Benchtop LCR meters typically have selectable test frequencies of more than 100 kHz. They often include possibilities to superimpose a DC voltage or current on the AC measuring signal. While some meters offer the possibility to externally supply these DC voltages or currents other devices supply them internally. An EMF METER is a test & metrology instrument for measuring electromagnetic fields (EMF). Majority of them measure the electromagnetic radiation flux density (DC fields) or the change in an electromagnetic field over time (AC fields). There are single axis and tri-axis instrument versions. Single axis meters cost less than tri-axis meters, but take longer to complete a test because the meter only measures one dimension of the field. Single axis EMF meters have to be tilted and turned on all three axes to complete a measurement. On the other hand, tri-axis meters measure all three axes simultaneously, but are more expensive. An EMF meter can measure AC electromagnetic fields, which emanate from sources such as electrical wiring, while GAUSSMETERS / TESLAMETERS or MAGNETOMETERS measure DC fields emitted from sources where direct current is present. The majority of EMF meters are calibrated to measure 50 and 60 Hz alternating fields corresponding to the frequency of US and European mains electricity. There are other meters which can measure fields alternating at as low as 20 Hz. EMF measurements can be broadband across a wide range of frequencies or frequency selective monitoring only the frequency range of interest. A CAPACITANCE METER is a test equipment used to measure capacitance of mostly discrete capacitors. Some meters display the capacitance only, whereas others also display leakage, equivalent series resistance, and inductance. Higher end test instruments use techniques such as inserting the capacitor-under-test into a bridge circuit. By varying the values of the other legs in the bridge so as to bring the bridge into balance, the value of the unknown capacitor is determined. This method ensures greater precision. The bridge may also be capable to measure series resistance and inductance. Capacitors over a range from picofarads to farads may be measured. Bridge circuits do not measure leakage current, but a DC bias voltage can be applied and the leakage measured directly. Many BRIDGE INSTRUMENTS can be connected to computers and data exchange be made to download readings or to control the bridge externally. Such bridge instruments aso offer go / no go testing for automation of tests in a fast paced production & quality control environment. Yet, another test instrument, a CLAMP METER is an electrical tester combining a voltmeter with a clamp type current meter. Most modern versions of clamp meters are digital. Modern clamp meters have most of the basic functions of a Digital Multimeter, but with the added feature of a current transformer built into the product. When you clamp the instrument’s “jaws” around a conductor carrying a large ac current, that current is coupled through the jaws, similar to the iron core of a power transformer, and into a secondary winding which is connected across the shunt of the meter’s input, the principle of operation resembling much that of a transformer. A much smaller current is delivered to the meter’s input due to the ratio of the number of secondary windings to the number of primary windings wrapped around the core. The primary is represented by the one conductor around which the jaws are clamped. If the secondary has 1000 windings, then the secondary current is 1/1000 the current flowing in the primary, or in this case the conductor being measured. Thus, 1 amp of current in the conductor being measured would produce 0.001 amps of current at the input of the meter. With clamp meters much larger currents can be easily measured by increasing the number of turns in the secondary winding. As with most of our test equipment, advanced clamp meters offer logging capability. GROUND RESISTANCE TESTERS are used for testing the earth electrodes and the soil resistivity. The instrument requirements depend on the range of applications. Modern clamp-on ground testing instruments simplify ground loop testing and enable non-intrusive leakage current measurements. Among the ANALYZERS we sell are OSCILLOSCOPES without doubt one of the most widely used equipment. An oscilloscope, also called an OSCILLOGRAPH, is a type of electronic test instrument that allows observation of constantly varying signal voltages as a two-dimensional plot of one or more signals as a function of time. Non-electrical signals like sound and vibration can also be converted to voltages and displayed on oscilloscopes. Oscilloscopes are used to observe the change of an electrical signal over time, the voltage and time describe a shape which is continuously graphed against a calibrated scale. Observation and analysis of the waveform reveals us properties such as amplitude, frequency, time interval, rise time, and distortion. Oscilloscopes can be adjusted so that repetitive signals can be observed as a continuous shape on the screen. Many oscilloscopes have storage function that allows single events to be captured by the instrument and displayed for a relatively long time. This allows us to observe events too fast to be directly perceptible. Modern oscilloscopes are lightweight, compact and portable instruments. There are also miniature battery-powered instruments for field service applications. Laboratory grade oscilloscopes are generally bench-top devices. There is a vast variety of probes and input cables for use with oscilloscopes. Please contact us in case you need advice about which one to use in your application. Oscilloscopes with two vertical inputs are called dual-trace oscilloscopes. Using a single-beam CRT, they multiplex the inputs, usually switching between them fast enough to display two traces apparently at once. There are also oscilloscopes with more traces; four inputs are common among these. Some multi-trace oscilloscopes use the external trigger input as an optional vertical input, and some have third and fourth channels with only minimal controls. Modern oscilloscopes have several inputs for voltages, and thus can be used to plot one varying voltage versus another. This is used for example for graphing I-V curves (current versus voltage characteristics) for components such as diodes. For high frequencies and with fast digital signals the bandwidth of the vertical amplifiers and sampling rate must be high enough. For-general purpose use a bandwidth of at least 100 MHz is usually sufficient. A much lower bandwidth is sufficient for audio-frequency applications only. Useful range of sweeping is from one second to 100 nanoseconds, with appropriate triggering and sweep delay. A well-designed, stable, trigger circuit is required for a steady display. The quality of the trigger circuit is key for good oscilloscopes. Another key selection criteria is the sample memory depth and sample rate. Basic level modern DSOs now have 1MB or more of sample memory per channel. Often this sample memory is shared between channels, and can sometimes only be fully available at lower sample rates. At the highest sample rates the memory may be limited to a few 10's of KB. Any modern ''real-time'' sample rate DSO will have typically 5-10 times the input bandwidth in sample rate. So a 100 MHz bandwidth DSO would have 500 Ms/s - 1 Gs/s sample rate. Greatly increased sample rates have largely eliminated the display of incorrect signals that was sometimes present in the first generation of digital scopes. Most modern oscilloscopes provide one or more external interfaces or buses such as GPIB, Ethernet, serial port, and USB to allow remote instrument control by external software. Here is a list of different oscilloscope types: CATHODE RAY OSCILLOSCOPE DUAL-BEAM OSCILLOSCOPE ANALOG STORAGE OSCILLOSCOPE DIGITAL OSCILLOSCOPES MIXED-SIGNAL OSCILLOSCOPES HANDHELD OSCILLOSCOPES PC-BASED OSCILLOSCOPES A LOGIC ANALYZER is an instrument that captures and displays multiple signals from a digital system or digital circuit. A logic analyzer may convert the captured data into timing diagrams, protocol decodes, state machine traces, assembly language. Logic Analyzers have advanced triggering capabilities, and are useful when the user needs to see the timing relationships between many signals in a digital system. MODULAR LOGIC ANALYZERS consist of both a chassis or mainframe and logic analyzer modules. The chassis or mainframe contains the display, controls, control computer, and multiple slots into which the data-capturing hardware is installed. Each module has a specific number of channels, and multiple modules can be combined to obtain a very high channel count. The ability to combine multiple modules to obtain a high channel count and the generally higher performance of modular logic analyzers makes them more expensive. For the very high end modular logic analyzers, the users may need to provide their own host PC or purchase an embedded controller compatible with the system. PORTABLE LOGIC ANALYZERS integrate everything into a single package, with options installed at the factory. They generally have lower performance than modular ones, but are economical metrology tools for general purpose debugging. In PC-BASED LOGIC ANALYZERS, the hardware connects to a computer through a USB or Ethernet connection and relays the captured signals to the software on the computer. These devices are generally much smaller and less expensive because they make use of a personal computer’s existing keyboard, display and CPU. Logic analyzers can be triggered on a complicated sequence of digital events, then capture large amounts of digital data from the systems under test. Today specialized connectors are in use. The evolution of logic analyzer probes has led to a common footprint that multiple vendors support, which provides added freedom to end users: Connectorless technology offered as several vendor-specific trade names such as Compression Probing; Soft Touch; D-Max is being used. These probes provide a durable, reliable mechanical and electrical connection between the probe and the circuit board. A SPECTRUM ANALYZER measures the magnitude of an input signal versus frequency within the full frequency range of the instrument. The primary use is to measure the power of the spectrum of signals. There are optical and acoustical spectrum analyzers as well, but here we will discuss only electronic analyzers that measure and analyze electrical input signals. The spectra obtained from electrical signals provides us information about frequency, power, harmonics, bandwidth…etc. The frequency is displayed on the horizonal axis and the signal amplitude on the vertical. Spectrum analyzers are widely used in the electronics industry for the analyses of the frequency spectrum of radio frequency, RF and audio signals. Looking at the spectrum of a signal we are able to reveal elements of the signal, and the performance of the circuit producing them. Spectrum analyzers are able to make a large variety of measurements. Looking at the methods used to obtain the spectrum of a signal we can categorize the spectrum analyzer types. - A SWEPT-TUNED SPECTRUM ANALYZER uses a superheterodyne receiver to down-convert a portion of the input signal spectrum (using a voltage-controlled oscillator and a mixer) to the center frequency of a band-pass filter. With a superheterodyne architecture, the voltage-controlled oscillator is swept through a range of frequencies, taking advantage of the full frequency range of the instrument. Swept-tuned spectrum analyzers are descended from radio receivers. Therefore swept-tuned analyzers are either tuned-filter analyzers (analogous to a TRF radio) or superheterodyne analyzers. In fact, in their simplest form, you could think of a swept-tuned spectrum analyzer as a frequency-selective voltmeter with a frequency range that is tuned (swept) automatically. It is essentially a frequency-selective, peak-responding voltmeter calibrated to display the rms value of a sine wave. The spectrum analyzer can show the individual frequency components that make up a complex signal. However it does not provide phase information, only magnitude information. Modern swept-tuned analyzers (superheterodyne analyzers, in particular) are precision devices that can make a wide variety of measurements. However, they are primarily used to measure steady-state, or repetitive, signals because they can't evaluate all frequencies in a given span simultaneously. The ability to evaluate all frequencies simultaneously is possible with only the real-time analyzers. - REAL-TIME SPECTRUM ANALYZERS: A FFT SPECTRUM ANALYZER computes the discrete Fourier transform (DFT), a mathematical process that transforms a waveform into the components of its frequency spectrum, of the input signal. The Fourier or FFT spectrum analyzer is another real-time spectrum analyzer implementation. The Fourier analyzer uses digital signal processing to sample the input signal and convert it to the frequency domain. This conversion is done using the Fast Fourier Transform (FFT). The FFT is an implementation of the Discrete Fourier Transform, the math algorithm used for transforming data from the time domain to the frequency domain. Another type of real-time spectrum analyzers, namely the PARALLEL FILTER ANALYZERS combine several bandpass filters, each with a different bandpass frequency. Each filter remains connected to the input at all times. After an initial settling time, the parallel-filter analyzer can instantaneously detect and display all signals within the analyzer's measurement range. Therefore, the parallel-filter analyzer provides real-time signal analysis. Parallel-filter analyzer is fast, it measures transient and time-variant signals. However, the frequency resolution of a parallel-filter analyzer is much lower than most swept-tuned analyzers, because the resolution is determined by the width of the bandpass filters. To get fine resolution over a large frequency range, you would need many many individual filters, making it costly and complex. This is why most parallel-filter analyzers, except the simplest ones in the market are expensive. - VECTOR SIGNAL ANALYSIS (VSA) : In the past, swept-tuned and superheterodyne spectrum analyzers covered wide frequency ranges from audio, thru microwave, to millimeter frequencies. In addition, digital signal processing (DSP) intensive fast Fourier transform (FFT) analyzers provided high-resolution spectrum and network analysis, but were limited to low frequencies due to the limits of analog-to-digital conversion and signal processing technologies. Today's wide-bandwidth, vector-modulated, time-varying signals benefit greatly from the capabilities of FFT analysis and other DSP techniques. Vector signal analyzers combine superheterodyne technology with high speed ADC's and other DSP technologies to offer fast high-resolution spectrum measurements, demodulation, and advanced time-domain analysis. The VSA is especially useful for characterizing complex signals such as burst, transient, or modulated signals used in communications, video, broadcast, sonar and ultrasound imaging applications. According to form factors, spectrum analyzers are grouped as benchtop, portable, handheld and networked. Benchtop models are useful for applications where the spectrum analyzer can be plugged into AC power,such as in a lab environment or manufacturing area. Bench top spectrum analyzers generally offer better performance and specifications than the portable or handheld versions. However they are generally heavier and have several fans for cooling. Some BENCHTOP SPECTRUM ANALYZERS offer optional battery packs, allowing them to be used away from a mains outlet. Those are referred to as a PORTABLE SPECTRUM ANALYZERS. Portable models are useful for applications where the spectrum analyzer needs to be taken outside to make measurements or carried while in use. A good portable spectrum analyzer is expected to offer optional battery-powered operation to allow the user to work in places without power outlets, a clearly viewable display to allow the screen to be read in bright sunlight, darkness or dusty conditions, light weight. HANDHELD SPECTRUM ANALYZERS are useful for applications where the spectrum analyzer needs to be very light and small. Handheld analyzers offer a limited capability as compared to larger systems. Advantages of handheld spectrum analyzers are however their very low power consumption, battery-powered operation while in the field to allow the user to move freely outside, very small size & light weight. Finally, NETWORKED SPECTRUM ANALYZERS do not include a display and they are designed to enable a new class of geographically-distributed spectrum monitoring and analysis applications. The key attribute is the ability to connect the analyzer to a network and monitor such devices across a network. While many spectrum analyzers have an Ethernet port for control, they typically lack efficient data transfer mechanisms and are too bulky and/or expensive to be deployed in such a distributed manner. The distributed nature of such devices enable geo-location of transmitters, spectrum monitoring for dynamic spectrum access and many other such applications. These devices are able to synchronize data captures across a network of analyzers and enable Network-efficient data transfer for a low cost. A PROTOCOL ANALYZER is a tool incorporating hardware and/or software used to capture and analyze signals and data traffic over a communication channel. Protocol analyzers are mostly used for measuring performance and troubleshooting. They connect to the network to calculate key performance indicators to monitor the network and speed-up troubleshooting activities. A NETWORK PROTOCOL ANALYZER is a vital part of a network administrator's toolkit. Network protocol analysis is used to monitor the health of network communications. To find out why a network device is functioning in a certain way, administrators use a protocol analyzer to sniff the traffic and expose the data and protocols that pass along the wire. Network protocol analyzers are used to - Troubleshoot hard-to-solve problems - Detect and identify malicious software / malware. Work with an Intrusion Detection System or a honeypot. - Gather information, such as baseline traffic patterns and network-utilization metrics - Identify unused protocols so that you can remove them from the network - Generate traffic for penetration testing - Eavesdrop on traffic (e.g., locate unauthorized Instant Messaging traffic or wireless Access Points) A TIME-DOMAIN REFLECTOMETER (TDR) is an instrument that uses time-domain reflectometry to characterize and locate faults in metallic cables such as twisted pair wires and coaxial cables, connectors, printed circuit boards,….etc. Time-Domain Reflectometers measure reflections along a conductor. In order to measure them, the TDR transmits an incident signal onto the conductor and looks at its reflections. If the conductor is of a uniform impedance and is properly terminated, then there will be no reflections and the remaining incident signal will be absorbed at the far end by the termination. However, if there is an impedance variation somewhere, then some of the incident signal will be reflected back to the source. The reflections will have the same shape as the incident signal, but their sign and magnitude depend on the change in impedance level. If there is a step increase in the impedance, then the reflection will have the same sign as the incident signal and if there is a step decrease in impedance, the reflection will have the opposite sign. The reflections are measured at the output/input of the Time-Domain Reflectometer and displayed as a function of time. Alternatively, the display can show the transmission and reflections as a function of cable length because the speed of signal propagation is almost constant for a given transmission medium. TDRs can be used to analyze cable impedances and lengths, connector and splice losses and locations. TDR impedance measurements provide designers the opportunity to perform signal integrity analysis of system interconnects and accurately predict the digital system performance. TDR measurements are widely used in board characterization work. A circuit board designer can determine the characteristic impedances of board traces, compute accurate models for board components, and predict board performance more accurately. There are many other areas of application for time-domain reflectometers. A SEMICONDUCTOR CURVE TRACER is a test equipment used to analyze the characteristics of discrete semiconductor devices such as diodes, transistors, and thyristors. The instrument is based on oscilloscope, but contains also voltage and current sources that can be used to stimulate the device under test. A swept voltage is applied to two terminals of the device under test, and the amount of current that the device permits to flow at each voltage is measured. A graph called V-I (voltage versus current) is displayed on the oscilloscope screen. Configuration includes the maximum voltage applied, the polarity of the voltage applied (including the automatic application of both positive and negative polarities), and the resistance inserted in series with the device. For two terminal devices like diodes, this is sufficient to fully characterize the device. The curve tracer can display all of the interesting parameters such as the diode's forward voltage, reverse leakage current, reverse breakdown voltage,…etc. Three-terminal devices such as transistors and FETs also use a connection to the control terminal of the device being tested such as the Base or Gate terminal. For transistors and other current based devices, the base or other control terminal current is stepped. For field effect transistors (FETs), a stepped voltage is used instead of a stepped current. By sweeping the voltage through the configured range of main terminal voltages, for each voltage step of the control signal, a group of V-I curves is generated automatically. This group of curves makes it very easy to determine the gain of a transistor, or the trigger voltage of a thyristor or TRIAC. Modern semiconductor curve tracers offer many attractive features such as intuitive Windows based user interfaces, I-V, C-V and pulse generation, and pulse I-V, application libraries included for every technology…etc. PHASE ROTATION TESTER / INDICATOR: These are compact and rugged test instruments to identify phase sequence on three-phase systems and open/de-energized phases. They are ideal for installing rotating machinery, motors and for checking generator output. Among the applications are the identification of proper phase sequences, detection of missing wire phases, determination of proper connections for rotating machinery, detection of live circuits. A FREQUENCY COUNTER is a test instrument that is used for measuring frequency. Frequency counters generally use a counter which accumulates the number of events occurring within a specific period of time. If the event to be counted is in electronic form, simple interfacing to the instrument is all that is needed. Signals of higher complexity may need some conditioning to make them suitable for counting. Most frequency counters have some form of amplifier, filtering and shaping circuitry at the input. Digital signal processing, sensitivity control and hysteresis are other techniques to improve performance. Other types of periodic events that are not inherently electronic in nature will need to be converted using transducers. RF frequency counters operate on the same principles as lower frequency counters. They have more range before overflow. For very high microwave frequencies, many designs use a high-speed prescaler to bring the signal frequency down to a point where normal digital circuitry can operate. Microwave frequency counters can measure frequencies up to almost 100 GHz. Above these high frequencies the signal to be measured is combined in a mixer with the signal from a local oscillator, producing a signal at the difference frequency, which is low enough for direct measurement. Popular interfaces on frequency counters are RS232, USB, GPIB and Ethernet similar to other modern instruments. In addition to sending measurement results, a counter can notify the user when user-defined measurement limits are exceeded. For details and other similar equipment, please visit our equipment website: http://www.sourceindustrialsupply.com КЛИКНЕТЕ Услуга за пронаоѓање на производи-локатор ПРЕТХОДНА СТРАНИЦА

Hardness Tester - Rockwell - Brinell - Vickers - Leeb - Microhardness - Universal - AGS-TECH Inc. - New Mexico - USA Тестери за цврстина AGS-TECH Inc. stocks a comprehensive range of hardness testers including ROCKWELL, BRINELL, VICKERS, LEEB, KNOOP, MICROHARDNESS TESTERS, UNIVERSAL HARDNESS TESTER, PORTABLE HARDNESS TESTING INSTRUMENTS, optical systems and software for measurement, data acquisition and analysis, test blocks, indenters, anvils and related accessories. Some of the brand name hardness testers we sell are BUEHLER, ELCOMETER, MITECH, SADT, SINOAGE, SINOWON ..... You can purchase brand new, refurbished or used equipment from us. Simply choose the product from the following catalogs and provide us the brand name and model of your choice: BUEHLER Hardness Testing Catalog ELCOMETER Inspection Equipment Catalog (does offer Physical Test Equipment , Concrete Inspection Equipment, Concrete Test Hammers , Hardness & Scratch Resistance Testers ) MITECH MH600 P ortable Hardness Tester MITECH Hardness Testers P roduct Comparison Table MITUTOYO Hardness Testing Machines SADT-SINOAGE B rand M etrology and T est E quipment Catalog SINOWON Rockwell Hardness Tester SINOWON Portable Ultrasonic Hardness Tester One of the most common tests for assessing the mechanical properties of materials is the hardness test. Hardness of a material is its resistance to permanent indentation. One may also say hardness is a material’s resistance to scratching and to wear. There are several techniques to measure the hardness of materials using various geometries and materials. The measurement results are not absolute, they are more of a relative comparative indicator, because the results depend on the shape of the indenter and the applied load. Our portable hardness testers can generally run any hardness test listed above. They can be configured for particular geometric features and materials such as hole interiors, gear teeth…etc. Let us briefly go over the various hardness test methods. BRINELL TEST : In this test, a steel or tungsten carbide ball with 10 mm diameter is pressed against a surface with a load of 500, 1500 or 3000 Kg force. Brinell hardness number is the ratio of the load to the curved area of indentation. A Brinell test leaves behind different types of impressions on the surface depending on the tested material’s condition. For example, on annealed materials a rounded profile is left behind whereas on cold-worked materials we observe a sharp profile. Tungsten carbide indenter balls are recommended for Brinell hardness numbers higher than 500. For harder workpiece materials a 1500 Kg or 3000 Kg load is recommended so that the impressions left behind are sufficiently large for accurate measurement. Because of the fact that impressions made by the same indenter at different loads are not geometrically similar, the Brinell hardness number depends on the load used. Therefore one should always note the load employed on the test results. Brinell test is well suited for materials between low to medium hardness. ROCKWELL TEST : In this test the depth of penetration is measured. The indenter is pressed on the surface initially with a minor load and then a major load. The difference in the penetration debth is a measure of hardness. Several Rockwell hardness scales exist employing different loads, indenter materials and geometries. The Rockwell hardness number is read directly from a dial on the testing machine. For example, if the hardness number is 55 using the C scale, it is written as 55 HRC. VICKERS TEST : Sometimes also referred to as the DIAMOND PYRAMID HARDNESS TEST, it uses a pyramid-shaped diamond indenter with loads ranging from 1 to 120 Kg. The Vickers hardness number is given by HV=1.854P / square L. The L here is the diagonal length of the diamond pyramid. The Vickers test gives basically the same hardness number regardless of the load. The Vickers test is suitable for testing materials with a wide range of hardness including very hard materials. KNOOP TEST : In this test, we use a diamond indenter in the shape of an elongated pyramid and loads between 25g to 5 Kg. The Knoop hardness number is given as HK=14.2P / square L. Here the letter L is the length of the elongated diagonal. The size of indentations in Knoop tests is relatively small, in the range of 0.01 to 0.10 mm. Due to this small number surface preparation for the material is very important. Test results should cite the load applied because the hardness number obtained depends on the applied load. Because light loads are used, the Knoop test is considered a MICROHARDNESS TEST. The Knoop test is therefore suitable for very small, thin specimens, brittle materials such as gemstones, glass and carbides, and even for measuring the hardness of individual grains in a metal. LEEB HARDNESS TEST : It is based on rebound technique measuring the Leeb hardness. It is an easy and industrially popular method. This portable method is mostly used for testing sufficiently large workpieces above 1 kg. An impact body with a hard metal test tip is propelled by spring force against the workpiece surface. When the impact body hits the workpiece, surface deformation takes place which will result in loss of kinetic energy. Velocity measurements reveal this loss in kinetic energy. When the impact body passes coil at a precise distance from the surface, a signal voltage is induced during the impact and rebound phases of the test. These voltages are proportional to the velocity. Using electronic signal processing one gets the Leeb hardness value from display. Our PORTABLE HARDNESS TESTERS from SADT / HARTIP HARDNESS TESTER SADT HARTIP2000/HARTIP2000 D&DL : This is an innovative portable Leeb hardness tester with newly patented technology, which makes HARTIP 2000 a universal angle (UA) impact direction hardness tester. There is no need to set up impact direction when taking measurements at any angle. Therefore, HARTIP 2000 offers a linear accuracy compared to the angle compensating method. HARTIP 2000 is also a cost saving hardness tester and has many other features. The HARTIP2000 DL is equipped with SADT unique D and DL 2-in-1 probe. SADT HARTIP1800 Plus/1800 Plus D&DL : This device is an advanced state-of-the-art palm sized metal hardness tester with many new features. Using a patented technology, SADT HARTIP1800 Plus is a new generation product. It has a high accuracy of +/-2 HL (or 0.3% @HL800) with high contract OLED display and wide environmental temperature range (-40ºC~60ºC). Apart from huge memories in 400 blocks with 360k data, HARTIP1800 Plus can download measured data to PC and printout to mini-printer by USB port and wirelessly with internal blue-tooth module. The battery can be charged simply from USB port. It has a customer re-calibration and statics function. HARTIP 1800 plus D&DL is equipped with two-in-one probe. With unique two-in-one probe, HARTIP1800plus D&DL can convert between probe D and probe DL simply by changing impact body. It’s more economical than buying them individually. It has the same configuration with HARTIP1800 plus except two-in-one probe. SADT HARTIP1800 Basic/1800 Basic D&DL : This is a basic model for HARTIP1800plus. With most of core functions of HARTIP1800 plus and a lower price, HARTIP1800 Basic is a good choice for the customer with limited budget. HARTIP1800 Basic also can be equipped with our unique D/DL two-in-one impact device. SADT HARTIP 3000 : This is an advanced hand-held digital metal hardness tester with high accuracy, wide measurement range and ease of operation. It is suitable for testing the hardness of all metals especially on site for large structural and assembled components, which are widely used in the power, petrochemical, aerospace, automotive and machine building industries. SADT HARTIP1500/HARTIP1000 : This is an integrated handheld metal hardness tester that combines impact device (probe) and processor into one unit. The size is much smaller than the standard impact device, which allows HARTIP 1500/1000 to meet not only normal measurement conditions, but also can take measurements at narrow spaces. HARTIP 1500/1000 is suitable for testing the hardness of almost all ferrous and nonferrous materials. With its new technology, its accuracy is improved to a higher level than the standard type. HARTIP 1500/1000 is one of the most economic hardness testers in its class. BRINELL HARDNESS READING AUTOMATIC MEASURING SYSTEM / SADT HB SCALER : HB Scaler is an optical measuring system which can automatically measure the size of indentation from Brinell hardness tester and gives the Brinell hardness readings. All values and indentation images can be saved in PC. With the software, all values can be processed and printed out as a report. Our BENCH HARDNESS TESTER products from SADT are: SADT HR-150A ROCKWELL HARDNESS TESTER : The manually operated HR-150A Rockwell hardness tester is known for its perfection and ease of operation. This machine uses the standard preliminary test force of 10kgf and main loads of 60/100/150 kilograms while conforming to the international Rockwell standard. After each test, the HR-150A shows the Rockwell B or Rockwell C hardness value directly on the dial indicator. The preliminary test force has to be applied manually, followed by applying the main load by means of the lever at the right side of the hardness tester. After unloading, the dial indicates the requested hardness value directly with high accuracy and repeatability. SADT HR-150DT MOTORIZED ROCKWELL HARDNESS TESTER : This series of hardness testers are recognized for their accuracy and ease of operation, function entirely conforming to the international Rockwell standard. Depending on the combination of indenter type and applied total test force, a unique symbol is given to each Rockwell scale. HR-150DT and HRM-45DT feature both specific Rockwell scales of HRC and HRB on a dial. The appropriate force should be adjusted manually, using the dial on the right side of the machine. After application of the preliminary force, the HR150DT and HRM-45DT will proceed with a fullly automated testing: loading, waiting, unloading, and at the end will display the hardness. SADT HRS-150 DIGITAL ROCKWELL HARDNESS TESTER : The HRS-150 digital Rockwell hardness tester is designed for ease of use and safety of operation. It conforms with the international Rockwell standard. Depending on the combination of indenter type and applied total test force, a unique symbol is given to each Rockwell scale. The HRS-150 will automatically show your selection of a specific Rockwell scale on the LCD display, and will indicate which load is being used. The integrated autobrake mechanism allows the preliminary test force to be applied manually without the possibility of an error. After application of the preliminary force, the HRS-150 will proceed with a fully automatic test: loading, dwell time, unloading, and computation of the hardness value and its display. Connected to the included printer through an RS232 output, it’s possible to print out all results. Our BENCH TYPE SUPERFICIAL ROCKWELL HARDNESS TESTER products from SADT are: SADT HRM-45DT MOTORIZED SUPERFICIAL ROCKWELL HARDNESS TESTER : This series hardness testers are recognized for their accuracy and ease of operation, perform entirely conforming to the international Rockwell standard. Depending on the combination of indenter type and applied total test force, a unique symbol is given to each Rockwell scale. HR-150DT and HRM-45DT feature both of the specific Rockwell scales HRC and HRB on a dial. The appropriate force should be adjusted manually, using the dial on the right side of the machine. After application of the preliminary force, the HR150DT and HRM-45DT will proceed with a fullly automatic test process: loading, dwelling, unloading, and at the end will display the hardness. SADT HRMS-45 SUPERFICIAL ROCKWELL HARDNESS TESTER : HRMS-45 Digital Superficial Rockwell Hardness Tester is a novel product integrating advanced mechanical and electronic technologies. The dual display of LCD and LED digital diodes, make it an upgraded product version of the standard type superficial Rockwell tester. It measures the hardness of ferrous, nonferrous metals and hard materials, carburized and nitrided layers, and other chemically treated layers. It is also used for the measurement of hardness of thin pieces. SADT XHR-150 PLASTIC ROCKWELL HARDNESS TESTER : XHR-150 plastics Rockwell hardness tester adopts a motorized testing method, testing force can be loaded, kept at dwelling and unloaded automatically. Human error is minimized and easy to operate. It is used to measure hard plastics, hard rubbers, aluminum, tin, copper, soft steel, synthetic resins, tribologic materials, etc. Our BENCH TYPE VICKERS HARDNESS TESTER products from SADT are: SADT HVS-10/50 LOW LOAD VICKERS HARDNESS TESTER : This low load Vicker’s hardness tester with digital display is a new hi-tech product integrating mechanical and photoelectrical technologies. As a substitute for traditional small-load Vicker’s hardness testers, it features an easy operation and good reliability, which is specially designed for testing small, thin samples or parts after surface coating. Suitable for research institutes, industrial labs and QC departments, this is an ideal hardness testing instrument for research and measurement purposes. It offers integration of computer programming technology, high resolution optical measuring system and photoelectrical technique, soft key input, light source adjustment, selectable testing model, conversion tables, pressure-holding time, file number input and data saving functions. It has a big LCD screen to display the test model, test pressure, indention length, hardness values, pressure holding time and the numbers of tests. Offers also date recording, test results recording and data processing, printing output function, through an RS232 interface. SADT HV-10/50 LOW LOAD VICKERS HARDNESS TESTER : These low load Vickers hardness testers are new hi-tech products integrating mechanical and photoelectrical technologies. These testers are specially designed for testing small and thin samples and parts after surface coating. Suitable for research institutes, industrial labs and QC departments. Key features and functions are microcomputer control, adjustment of light source via soft keys, adjustment of pressure holding time and LED/LCD display, its unique measurement conversion device and unique micro eyepiece one-time measurement readout device that ensures easy use and high accuracy. SADT HV-30 VICKERS HARDNESS TESTER : The HV-30 model Vickers hardness tester is specially designed for testing small, thin samples and parts after surface coating. Suitable for research institutes, factory labs and QC departments, these are ideal hardness testing instruments for research and test purposes. Key features and functions are micro computer control, automatic loading and unloading mechanism, adjustment of lighting source via hardware, adjustment of pressure holding time (0~30s), unique measurement conversion device and unique micro eyepiece one-time measurement readout device, ensuring easy use and high accuracy. Our BENCH TYPE MICRO HARDNESS TESTER products from SADT are: SADT HV-1000 MICRO HARDNESS TESTER / HVS-1000 DIGITAL MICRO HARDNESS TESTER : This product is especially well suited for high precision hardness testing of small and thin samples such as sheet, foil, coatings, ceramic products and hardened layers. To ensure a satisfactory indentation, the HV1000 / HVS1000 features automatic loading and unloading operations, a very accurate loading mechanism and a robust lever system. The micro-computer controlled system ensures an absolutely precise hardness measurement with adjustable dwell time. SADT DHV-1000 MICRO HARDNESS TESTER / DHV-1000Z DIGITAL VICKERS HARDNESS TESTER : These micro Vickers hardness testers made with a unique and precise design are able to produce a clearer indentation and hence a more accurate measurement. By means of a 20 × lens and a 40 × lens the instrument has a wider measurement field and a broader application range. Equipped with a digital microscope, on its LCD screen it shows the measuring methods, the test force, the indentation length, the hardness value, the dwell time of the test force as well as the number of the measurements. In addition, it is equipped with an interface linked to a digital camera and a CCD video camera. This tester is widely used for measuring ferrous metals, non-ferrous metals, IC thin sections, coatings, glass, ceramics, precious stones, quench hardened layers and more. SADT DXHV-1000 DIGITAL MICRO HARDNESS TESTER : These micro Vickers hardness testers made with a unique and precise are able to produce a clearer indentation and hence more accurate measurements. By means of a 20 × lens and a 40 × lens the tester has a wider measurement field and a broader application range. With an automatically turning device ( the automatically turning turret ), the operation has become easier; and with a threaded interface, it can be linked to a digital camera and a CCD video camera. First the device lets the LCD touch screen to be used, thus allowing the operation to be more human controlled. The device has capabilities such as direct reading of the measurements, the easy change of the hardness scales, the saving of the data, the printing and the connection with the RS232 interface. This tester is widely used for measuring ferrous metals, non-ferrous metals, IC thin sections, coatings, glass, ceramics, precious stones; thin plastic sections, quench hardened layers and more. Our BENCH TYPE BRINELL HARDNESS TESTER / MULTI-PURPOSE HARDNESS TESTER products from SADT are: SADT HD9-45 SUPERFICIAL ROCKWELL & VICKERS OPTICAL HARDNESS TESTER : This device serves the purpose of measuring the hardness of ferrous, nonferrous metals, hard metals, carburized and nitrided layers and chemically treated layers and thin pieces. SADT HBRVU-187.5 BRINELL ROCKWELL & VICKERS OPTICAL HARDNESS TESTER : This instrument is used for determining the Brinell, Rockwell and Vickers hardness of ferrous, nonferrous metals, hard metals, carburized layers and chemically treated layers. It can be used in plants, scientific & research institutes, laboratories and colleges. SADT HBRV-187.5 BRINELL ROCKWELL & VICKERS HARDNESS TESTER (NOT OPTICAL) : This instrument is used for determining the Brinell, Rockwell and Vickers hardness of ferrous, non-ferrous metals, hard metals, carburized layers and chemically treated layers. It can be used in factories, scientific & research institutes, laboratories and colleges. It’s not an optical type hardness tester. SADT HBE-3000A BRINELL HARDNESS TESTER : This automatic Brinell hardness tester features a wide measurement range up to 3000 Kgf with a high accuracy conforming to DIN 51225/1 standard. During the automatic test cycle the applied force will be controlled by a closed loop system guaranteeing a constant force on the work piece, conforming to DIN 50351 standard. The HBE-3000A comes completely with a reading microscope with enlargement factor 20X and a micrometer resolution of 0.005 mm. SADT HBS-3000 DIGITAL BRINELL HARDNESS TESTER : This digital Brinell hardness tester is a new generation state-of-the-art device. It can be used to determine the Brinell hardness of ferrous and non-ferrous metals. The tester offers electronic auto loading, computer software programming, high power optical measurement, photosensor and other features. Each operational process and test result can be displayed on its large LCD screen. The test results can be printed. Device is suitable for manufacturing environments, colleges and scientific institutions. SADT MHB-3000 DIGITAL ELECTRONIC BRINELL HARDNESS TESTER : This instrument is an integrated product combining optical, mechanical and electronic techniques, adopting a precise mechanical structure and computer controlled closed-circuit system. The instrument loads and unloads the testing force with its motor. Using a 0.5% accuracy compression sensor to feedback the information and the CPU to control, the instrument compensates automatically for the varying testing forces. Equipped with a digital micro eyepiece on the instrument, the length of indentation can be measured directly. All testing data such as the test method, the test force value, the length of test indentation, the hardness value and the dwell time of testing force can be shown on the LCD screen. There is no need to input the value of the diagonal length for the indentation and no need to look up the hardness value from the hardness table. Therefore the read data is more accurate and operation of this instrument is easier. For details and other similar equipment, please visit our equipment website: http://www.sourceindustrialsupply.com КЛИКНЕТЕ Услуга за пронаоѓање на производи-локатор PREVIOUS PAGE

Glass and Ceramic Manufacturing, Hermetic Packages Seals and Bonding, Tempered Bulletproof Glass, Blow Moulding, Optical Grade Glass, Conductive Glass, Molding Формирање и обликување на стакло и керамика The type of glass manufacturing we offer are container glass, glass blowing, glass fiber & tubing & rod, domestic and industrial glassware, lamp and bulb, precision glass moulding, optical components and assemblies, flat & sheet & float glass. We perform both hand forming as well as machine forming. Our popular technical ceramic manufacturing processes are die pressing, isostatic pressing, hot isostatic pressing, hot pressing, slip casting, tape casting, extrusion, injection moulding, green machining, sintering or firing, diamond grinding, hermetic assemblies. We recommend that you click here to DOWNLOAD our Schematic Illustrations of Glass Forming and Shaping Processes by AGS-TECH Inc. DOWNLOAD our Schematic Illustrations of Technical Ceramic Manufacturing Processes by AGS-TECH Inc. These downloadable files with photos and sketches will help you better understand the information we are providing you below. • CONTAINER GLASS MANUFACTURE: We have automated PRESS AND BLOW as well as BLOW AND BLOW lines for manufacturing. In the blow and blow process we drop a gob into blank mold and form the neck by applying a blow of compressed air from top. Immediately following this, compressed air is blown a second time from the other direction through the container neck to form the pre-form of the bottle. This pre-form is then transferred to the actual mold, reheated to soften and compressed air is applied to give the pre-form its final container shape. More explicitly, it is pressurized and pushed against the walls of the blow mold cavity to take its desired shape. Finally, the manufactured glass container is transfered into an annealing oven for subsequent reheating and removal of stresses produced during the molding and is cooled in a controlled fashion. In the press and blow method, molten gobs are put into a parison mold (blank mold) and pressed into the parison shape (blank shape). The blanks are then transfered to blow molds and blown similar to the process described above under “Blow and Blow Process”. Subsequent steps like annealing and stress relieve are similar or the same. • GLASS BLOWING : We have been manufacturing glass products using conventional hand blowing as well as using compressed air with automated equipment. For some orders conventional blowing is necessary, such as projects involving glass art work, or projects that require a smaller number of parts with loose tolerances, prototyping / demo projects….etc. Conventional glass blowing involves the dipping of a hollow metal pipe into a pot of molten glass and rotating the pipe for collecting some amount of the glass material. The glass collected on the tip of the pipe is rolled on flat iron, shaped as desired, elongated, re-heated and air blown. When ready, it is inserted into a mould and air is blown. The mould cavity is wet to avoid contact of the glass with metal. The water film acts like a cushion between them. Manual blowing is a labor intensive slow process and only suitable for prototyping or items of high value, not suitable for inexpensive per piece high volume orders. • MANUFACTURING OF DOMESTIC & INDUSTRIAL GLASSWARE : Using various types of glass material a large variety of glassware is being produced. Some glasses are heat resistant and suitable for laboratory glassware whereas some are good enough for withstanding dishwashers for many times and are fit for making domestic products. Using Westlake machines tens of thousands of pieces of drinking glasses are being produced per day. To simplify, molten glass is collected by vacuum and inserted into moulds to make the pre-forms. Then air is blown into the moulds, these are transfered to another mould and air is blown again and the glass takes its final shape. Like in hand blowing, these moulds are kept wet with water. Further stretching is part of the finishing operation where the neck is being formed. Excess glass is burnt off. Thereafter the controlled re-heating and cooling process described above follows. • GLASS TUBE & ROD FORMING : The main processes we use for manufacturing of glass tubes are the DANNER and VELLO processes. In the Danner Process, glass from a furnace flows and falls on an inclined sleeve made of refractory materials. The sleeve is carried on a rotating hollow shaft or blowpipe. The glass is then wrapped around the sleeve and forms a smooth layer flowing down the sleeve and over the tip of the shaft. In the case of tube forming, air is blown through a blowpipe with hollow tip, and in the case of rod forming we use solid tips on the shaft. The tubes or rods are then drawn over carrying rollers. The dimensions like wall thickness and diameter of the glass tubes are adjusted to desired values by setting the diameter of the sleeve and blowing air pressure to a desired value, adjusting the temperature, rate of flow of glass and speed of drawing. The Vello glass tube manufacturing process on the other hand involves glass that travels out a furnace and into a bowl with a hollow mandrel or bell. The glass then goes through the air space between the mandrel and the bowl and takes the shape of a tube. Thereafter it travels over rollers to a drawing machine and is cooled. At the end of the cooling line cutting and final processing takes place. The tube dimensions can be adjusted just like in the Danner process. When comparing the Danner to Vello process, we can say that Vello process is a better fit for large quantity production whereas the Danner process may be a better fit for precise smaller volume tube orders. • PROCESSING OF SHEET & FLAT & FLOAT GLASS : We have large quantities of flat glass in thicknesses ranging from submilimeter thicknesses to several centimeters. Our flat glasses are of almost optical perfection. We offer glass with special coatings such as optical coatings, where chemical vapor deposition technique is used to put coatings such as antireflection or mirror coating. Also transparent conductive coatings are common. Also available are hydrophobic or hydrophilic coatings on glass, and coating that makes glass self-cleaning. Tempered, bulletproof and laminated glasses are yet other popular items. We cut glass into desired shape with desired tolerances. Other secondary operations such as curving or bending flat glass are available. • PRECISION GLASS MOLDING : We use this technique mostly for manufacturing precision optical components without the need for more expensive and time consuming techniques like grinding, lapping and polishing. This technique is not always sufficient for making the best of the best optics, but in some cases like consumer products, digital cameras, medical optics it can be a less expensive good option for high volume manufacturing. Also it has an advantage over the other glass forming techniques where complex geometries are required, such as in the case of aspheres. The basic process involves loading of the lower side of our mold with the glass blank, evacuation of the process chamber for oxygen removal, near closing of the mold, fast and isothermal heating of die and glass with infrared light, further closing of the mould halves to press the softened glass slowly in a controlled fashion to the desired thickness, and finally cooling of the glass and filling the chamber with nitrogen and removal of the product. Precise temperature control, mould closure distance, mould closure force, matching the coefficients of expansion of the mold and glass material are key in this process. • MANUFACTURE OF GLASS OPTICAL COMPONENTS AND ASSEMBLIES : Besides precision glass molding, there are a number of valuable processes we use for making high quality optical components and assemblies for demanding applications. Grinding, lapping and polishing of optical grade glasses in fine special abrasive slurries is an art and science for making optical lenses, prisms, flats and more. Surface flatness, waviness, smoothness and defect free optical surfaces require lots of experience with such processes. Small changes in environment can result in out of specification products and bring the manufacturing line to a stop. There are cases where a single wipe on the optical surface with a clean cloth can make a product meet the specifications or fail the test. Some popular glass materials used are fused silica, quartz, BK7. Also the assembly of such components requires specialized niche experience. Sometimes special glues are being used. However, sometimes a technique called optical contacting is the best choice and involves no material in between attached optical glasses. It consists of physically contacting flat surfaces to attach to each other without glue. In some cases mechanical spacers, precision glass rods or balls, clamps or machined metal components are being used to assemble the optical components at certain distances and with certain geometric orientations to each other. Let us examine some of our popular techniques for manufacturing high end optics. GRINDING & LAPPING & POLISHING : The rough shape of the optical component is obtained with grinding a glass blank. Thereafter lapping and polishing are carried out by rotating and rubbing the rough surfaces of the optical components against tools with desired surface shapes. Slurries with tiny abrasive particles and fluid are being poured in between the optics and the shaping tools. The abrasive particle sizes in such slurries can be chosen according to the degree of flatness desired. The deviations of critical optical surfaces from desired shapes are expressed in terms of wavelengths of the light being used. Our high precision optics have tenth of a wavelength (Wavelength/10) tolerances or even tighter is possible. Besides surface profile, the critical surfaces are scanned and evaluated for other surface features and defects such as dimensions, scratches, chips, pits, specks...etc. The tight control of environmental conditions in the optical manufacturing floor and extensive metrology and testing requirements with state-of-the-art equipment make this a challenging branch of industry. • SECONDARY PROCESSES IN GLASS MANUFACTURING: Again, we are only limited with your imagination when it comes to secondary and finishing processes of glass. Here we list some of them: -Coatings on glass (optical, electrical, tribological, thermal, functional, mechanical...). As an example we can alter surface properties of glass making it for example reflect heat so that it keeps building interiors cool, or make one side infrared absorbing using nanotechnology. This helps keep the inside of buildings warm because the outermost surface layer of glass will absorb the infrared radiation inside the building and radiate it back to the inside. -Etching on glass -Applied Ceramic Labeling (ACL) -Engraving -Flame polishing -Chemical polishing -Staining MANUFACTURING OF TECHNICAL CERAMICS • DIE PRESSING : Consists of uniaxial compaction of granular powders confined in a die • HOT PRESSING : Similar to die pressing but with the addition of temperature to enhance densification. Powder or compacted preform is placed into graphite die and uniaxial pressure is applied while the die is kept at high temperatures such as 2000 C. Temperatures can be different depending on the type of ceramic powder being processed. For complicated shapes and geometries other subsequent processing such as diamond grinding may be needed. • ISOSTATIC PRESSING : Granular powder or die pressed compacts are placed in airtight containers and then into a closed pressure vessel with liquid inside. Thereafter they are compacted by increasing the pressure vessel’s pressure. The liquid inside the vessel transfers the pressure forces uniformly over the entire surface area of the airtight container. The material is thus compacted uniformly and takes the shape of its flexible container and its internal profile and features. • HOT ISOSTATIC PRESSING : Similar to isostatic pressing, but in addition to pressurized gas atmosphere, we sinter the compact at high temperature. Hot isostatic pressing results in additional densification and increased strength. • SLIP CASTING / DRAIN CASTING : We fill the mould with a suspension of micrometer sized ceramic particles and carrier liquid. This mixture is called “slip”. The mould has pores and therefore the liquid in the mixture is filtered into the mould. As a result, a cast is formed on the inner surfaces of the mould. After sintering, the parts can be taken out of the mould. • TAPE CASTING : We manufacture ceramic tapes by casting ceramic slurries onto flat moving carrier surfaces. The slurries contain ceramic powders mixed with other chemicals for binding and carrying purposes. As the solvents evaporate dense and flexible sheets of ceramic are left behind which can be cut or rolled as desired. • EXTRUSION FORMING : As in other extrusion processes, a soft mixture of ceramic powder with binders and other chemicals is passed through a die to acquire its cross-sectional shape and is then cut at desired lengths. The process is performed with cold or heated ceramic mixtures. • LOW PRESSURE INJECTION MOLDING : We prepare a mixture of ceramic powder with binders and solvents and heat it to a temperature where it can easily be pressed and forced into the tool cavity. Once the moulding cycle is complete, the part is ejected and the binding chemical is burned off. Using injection molding, we can obtain intricate parts at high volumes economically. Holes that are a tiny fraction of a milimeter on a 10mm thick wall are possible, threads are possible without forther machining, tolerances as tight as +/- 0.5% are possible and even lower when parts are machined, wall thicknesses in the order of 0.5mm to a length of 12.5 mm are possible as well as wall thicknesses of 6.5mm to a length of 150mm. • GREEN MACHINING : Using the same metal machining tools, we can machine pressed ceramic materials while they are still soft like chalk. Tolerances of +/- 1% are possible. For better tolerances we use diamond grinding. • SINTERING or FIRING : Sintering makes full densification possible. Significant shrinkage occurs on the green compact parts, but this is not a big problem since we take into account these dimensional changes when we design the part and tooling. Powder particles are bonded together and porosity induced by the compaction process is removed to great extent.. • DIAMOND GRINDING : The World’s hardest material “diamond” is being used to grind hard materials like ceramics and precision parts are obtained. Tolerances in the micrometer range and very smooth surfaces are being achieved. Due to its expense, we only consider this technique when we really need it. • HERMETIC ASSEMBLIES are those that practically speaking do not allow any exchange of matter, solids, liquids or gases between interfaces. Hermetic sealing is airtight. For example hermetic electronic enclosures are those that keep the sensitive interior contents of a packaged device unharmed by moisture, contaminants or gases. Nothing is 100% hermetic, but when we speak of hermeticity we mean that in practical terms, that there is hermeticity to the extent that the leak rate is so low that the devices are safe under normal environmental conditions for very long times. Our hermetic assemblies consist of metal, glass and ceramic components, metal-ceramic, ceramic-metal-ceramic, metal-ceramic-metal, metal to metal, metal-glass, metal-glass-metal, glass-metal-glass, glass-metal and glass to glass and all other combinations of metal-glass-ceramic bonding. We can for example metal coat the ceramic components so they can be strongly bonded to other components in the assembly and have excellent sealing capability. We have the know-how of coating optical fibers or feedthroughs with metal and soldering or brazing them to the enclosures, so no gases pass or leak into the enclosures. Therefore they are used for manufacturing electronic enclosures to encapsulate sensitive devices and protect them from the outer atmosphere. Besides their excellent sealing characteristics, other properties such as the thermal expansion coefficient, deformation resistance, non-outgassing nature, very long lifetime, nonconductive nature, thermal insulation properties, antistatic nature...etc. make glass and ceramic materials the choice for certain applications. Information on our facility producing ceramic to metal fittings, hermetic sealing, vacuum feedthroughs, high and ultrahigh vacuum and fluid control components can be found here: Hermetic Components Factory Brochure КЛИКНЕТЕ Услуга за пронаоѓање на производи-локатор ПРЕТХОДНА СТРАНИЦА

Private Labeling, White Labeling, Private Label, White Label AGS-TECH, Inc. е ваш Производител и добавувач на приватна и бела етикета. Од нас можете да набавите производи со вашиот бренд, лого и етикета. Многу од нашите готови производи може да ви бидат испорачани со името на вашата марка на нив, за да можете веднаш да започнете со продажба и промовирање на вашиот бренд. Приватно обележување и бело означување на вашите производи If you wish, after manufacturing your products, we can PRIVATE LABEL or WHITE LABEL your products with your name, your brand name or any name you wish. Private labeling or white labeling means a product is manufactured by one company and sold under another company's brand name or some other name. Retailers often use private labeling to offer many items to their clients, expand their catalogs, and undercut competitor pricing. If your company is planning to sell products under its name or adding new products to its current spectrum, private labeling may be an excellent option for you. Private labeling allows you to outsource the sourcing, procurement, manufacturing, importing, shipping & logistics and other aspects of the supply chain to another company. Private labeling will enable you to gain access to the entire supply chain without requiring you to build your own supply network infrastructure. There is a small difference between private labeling and white labeling. The main difference is that a private label product is sold exclusively through one seller or retailer, whereas a white label product can be sold to several buyers or retailers and resold by them to final customers. We can manufacture and supply many products to you with your private label and your brand name. Thus, your customers will only know you as their supplier. If you wish, we can oversee everything from the product's specifications, packaging, labeling, marking and everything else until the product is received by you. Here is a brief list of some industrial products we can supply you with YOUR BRAND NAME on them. Below list is in alphabetical order. Abrasives Adhesives Alarm Cabling Automation & Integration Equipment Automotive Accessories Automotive Components and Parts Automotive Test Equipment, Data Logger, Bu Engine Analyzer, Bearings & Bushings Bike and Biker Accessories Cables & Cabling Car Accessories Chains Coaxial Cables Computers Connectors & Adapters Construction Tools Consumer Electronics Containers Corporate Gifts Cutting Tools Drilling Tools Electric Chargers Electric Transformers Electric Vehicle Chargers Electronic Products and Accessories Embedded Computers Endoscopes Engine Parts EV Chargers Fasteners Fiberscopes Fiberoptic Cables Fiberoptic Devices Filters & Filtration Systems Flash Storage Devices Gaskets Gears Hand Tools Hose Crimping Machines Hydraulic Products & Components Hydraulic Reservoirs Imaging Systems Industrial Supplies Interconnects Leak Testing Machine Leather Work Gear & Gloves LED Lighting Lighting Products & Accessories Lubricants & Degreasers Machines Motorcycle Parts and Accessories Optical Transceivers Packages & Packaging Materials Phototherapy Devices Photovoltaic Components and Systems Plastic Products Pneumatic Products & Components Power Tools Racks, Pinions, Splines, Gears Rigging Hardware Ropes & Cords Rubber Products Sensors Speaker Cabling Storage Devices Switches Test Equipment Tools & Hardware Transceivers Transformers (Electrical) Tube Bending Machines Tube Endforming Machine USB Drives Valves Work Tools КЛИКНИ ТУКА Кликнете овде за да го пополните нашиот формулар - БАРАЊЕ ЗА ПРОИЗВОД ОД ПРИВАТНА ИЛИ БЕЛА ознака КЛИКНИ ТУКА Кликнете овде за да отидете на нашата страница за КАТАЛОГИ НА ПРОИЗВОДИ ОД ПРИВАТНА И БЕЛА ознака КЛИКНИ ТУКА Кликнете овде за да отидете на нашата страница за ПАКУВАЊЕ И БЕЛА ЕТИКЕТИРАЊЕ И ПРОИЗВОДИ, ПОТРЕБИ, УСЛУГИ 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.

LED Assemblies, Light Emitting Diodes Power Supply, Plastic Molded Lenses LED склопови на производи LED склоп - задно светло за мотоцикл LED склопови на производи AGS-TECH Inc. склопи обликувани пластични компоненти со диоди што емитуваат светлина - задни светла за мотоцикли Задно светло на мотоцикл со вградени диоди што емитуваат светлина Водоотпорно LED напојување Моќни LED светлосни склопови Пакување на производот според барањата на клиентите AGS-TECH нуди прилагодено пакување за вашите произведени производи Собрание на LED PCB Производство на LED улично осветлување ЛЕД драјвер за затемнување на задниот раб Склопови на LED PCB LED склопови со висока моќност LED драјвер со висока моќност ПРЕТХОДНА СТРАНИЦА

Photochemical Machining - PCM - Photo Etching - Chemical Milling - Blanking - Wet Etching - CM - Sheet Metal Components Хемиска обработка и фотохемиско бланирање CHEMICAL MACHINING (CM) technique is based on the fact that some chemicals attack metals and etch them. This results in removal of small layers of material from surfaces. We use reagents and etchants such as acids and alkaline solutions to remove material from surfaces. The hardness of the material is not a factor for etching. AGS-TECH Inc. frequently uses chemical machining for engraving metals, manufacturing printed-circuit boards and deburring of produced parts. Chemical machining is well suited for shallow removal up to 12 mm on large flat or curved surfaces, and CHEMICAL BLANKING of thin sheets. The chemical machining (CM) method involves low tooling and equipment costs and is advantageous over other ADVANCED MACHINING PROCESSES for low production runs. Typical material removal rates or cutting speeds in chemical machining are around 0.025 – 0.1 mm/min. Using CHEMICAL MILLING, we produce shallow cavities on sheets, plates, forgings and extrusions, either to meet design requirements or for reduction of weight in parts. The chemical milling technique can be used on a variety of metals. In our manufacturing processes, we deploy removable layers of maskants to control the selective attack by the chemical reagent on different areas of the workpiece surfaces. In microelectronic industry the chemical milling is widely used to fabricate miniature devices on chips and the technique is referred to as WET ETCHING. Some surface damage may result from chemical milling due to preferential etching and intergranular attack by the chemicals involved. This may result in deterioration of surfaces and roughening. One has to be careful prior to deciding to use chemical milling on metal castings, welded and brazed structures because uneven material removal may occur because the filler metal or the structural material may machine preferentially. In metal castings uneven surfaces may be obtained due to porosity and non-uniformity of the structure. CHEMICAL BLANKING: We use this method to produce features that penetrate through the thickness of the material, having the material removed by chemical dissolution. This method is an alternative to stamping technique we use in sheet metal manufacturing. Also in burr-free etching of printed-circuit boards (PCB) we deploy chemical blanking. PHOTOCHEMICAL BLANKING & PHOTOCHEMICAL MACHINING (PCM): Photochemical blanking is also known as PHOTOETCHING or PHOTO ETCHING, and is a modified version of chemical milling. Material is removed from flat thin sheets using photographic techniques and complex burr-free, stress-free shapes are blanked. Using photochemical blanking we manufacture fine and thin metal screens, printed-circuit cards, electric-motor laminations, flat precision springs. The photochemical blanking technique offers us the advantage of producing small parts, fragile parts without the need to manufacture difficult and expensive blanking dies that are used in traditional sheet metal manufacturing. Photochemical blanking does require skilled personnel, but the tooling costs are low, the process is easily automated and feasibility is high for medium to high volume production. Some disadvantages exist as is the case in every manufacturing process: Environmental concerns due to chemicals and safety concerns due to volatile liquids being used. Photochemical machining also known as PHOTOCHEMICAL MILLING, is the process of fabricating sheet metal components using a photoresist and etchants to corrosively machine away selected areas. Using photo etching we produce highly complex parts with fine details economically. The photochemical milling process is for us an economical alternative to stamping, punching, laser and water jet cutting for thin gauge precision parts. The photochemical milling process is useful for prototyping and allows for easy and quick changes when there is a change in design. It is an ideal technique for research & development. Phototooling is fast and inexpensive to produce. Most phototools cost less than $ 500 and can be produced within two days. Dimensional tolerances are well met with no burrs, no stress and sharp edges. We can start manufacturing a part within hours after receiving your drawing. We can use PCM on most commercially available metals and alloys such as include aluminium, brass, beryllium-copper, copper, molybdenum, inconel, manganese, nickel, silver, steel, stainless steel, zinc and titanium with thicknesses of 0.0005 to 0.080 in (0.013 to 2.0 mm). Phototools are exposed only to light and therefore do not wear out. Due to the cost of hard tooling for stamping and fine blanking, significant volume is required to justify the expense, which is not the case in PCM. We start the PCM process by printing the shape of the part onto optically clear and dimensionally stable photographic film. The phototool consists of two sheets of this film showing negative images of the parts meaning that the area that will become the parts is clear and all of the areas to be etched are black. We register the two sheets optically and mechanically to form the top and bottom halves of the tool. We cut the metal sheets to size, clean and then laminate on both sides with a UV-sensitive photoresist. We place the coated metal between the two sheets of the phototool and a vacuum is drawn to ensure intimate contact between the phototools and the metal plate. We then expose the plate to UV light that allows the areas of resist that are in the clear sections of the film to be hardened. After exposure we wash away the unexposed resist of the plate, leaving the areas to be etched unprotected. Our etching lines have driven-wheel conveyors to move the plates and arrays of spray nozzles above and below the plates. The etchant is typically an aqueous solution of acid such as ferric chloride, that is heated and directed under pressure to both sides of the plate. The etchant reacts with the unprotected metal and corrodes it away. After neutralizing and rinsing, we remove the remaining resist and the sheet of parts is cleaned and dried. Applications of photochemical machining include fine screens and meshes, apertures, masks, battery grids, sensors, springs, pressure membranes, flexible heating elements, RF and microwave circuits and components, semiconductor leadframes, motor and transformer laminations, metal gaskets and seals, shields and retainers, electrical contacts, EMI/RFI shields, washers. Some parts, such as semiconductor leadframes, are very complex and fragile that, despite volumes in the millions of pieces, they can only be produced by photo etching. The accuracy achievable with the chemical etching process offers us tolerances starting at +/-0.010mm depending on the material type and thickness. Features can be positioned with accuracies around +-5 microns. In PCM, the most economical way is to plan the largest sheet size possible consistent with the size and dimensional tolerances of the part. The more parts per sheet are produced the lower the unit labor cost per part. Material thickness affects costs and is proportional to the length of time to etch through. Most alloys etch at rates between 0.0005–0.001 in (0.013–0.025 mm) of depth per minute per side. In general, for steel, copper or aluminum workpieces with thicknesses up to 0.020 in (0.51 mm), part costs will be roughly $0.15–0.20 per square inch. As the geometry of the part becomes more complex, photochemical machining gains greater economic advantage over sequential processes such as CNC punching, laser or water-jet cutting, and electrical discharge machining. Contact us today with your project and let us provide you our ideas and suggestions. КЛИКНЕТЕ Услуга за пронаоѓање на производи-локатор ПРЕТХОДНА СТРАНИЦА

AGS-TECH Inc Past Present Mission - We specialize in Manufacturing, Fabrication, Assembly of Products, Custom Manufacturing of Components, Parts, Subassemblies. Our Manufacturing Past & Present Mission Основани сме под името AGS-Group во 1979 година како компанија за производство на индустриски производи и градежни материјали. Во 2002 година, напредната технолошка групација се откачи како AGS-TECH Inc. што ја одразува својата мисија на полето на технологијата и се фокусира на процесите на производство и изработка со поголема додадена вредност. Ние се држиме во првите редови на технологијата во областите на прилагодено производство на калапи и матрици, обликување на пластични и гумени делови, CNC обработка на метални и легирани делови, обработка на пластика, ковање и лиење метал, техничко формирање и обликување на керамика и стакло, печат и изработка на лим, производство на машински елементи, електронски компоненти и склопови, изработка и монтажа на оптички компоненти, нано-производство, микропроизводство, мезопроизводство, неконвенционално производство, индустриски компјутери и опрема за автоматизација, индустриски тестови и метролошки алатки и опрема, напредни инженерски и технички услуги. Нашата разлика од другите инженерски и производствени компании е дека ние сме способни да ви обезбедиме голем број компоненти, подсклопови, склопови и готови производи од еден единствен извор, имено AGS-TECH Inc. Нема друга компанија која може да ви обезбеди таков разновиден спектар на инженерски услуги и производствени способности. Нашата компанија е инкорпорирана во државата Ново Мексико-САД. Групата компании AGS има годишен обрт во опсег од повеќе милиони долари. Групата за напредна технологија AGS-TECH е дел од оваа поголема групација и сè уште расте од година во година. Членовите на нашиот технички тим поседуваат повеќе патенти во нивните области на експертиза, многумина имаат десетици публикации во меѓународно признати списанија и се пронаоѓачи со дипломирани дипломи од врвни универзитети во светот. Секојдневно нашите тимови ги прегледуваат нацртите доставени од клиентите, листовите со спецификации и сметката за материјали, разменуваат информации со клиентите, одржуваат инженерски состаноци и се консултираат меѓусебно, го даваат своето стручно мислење за нашите клиенти, ги менуваат и подобруваат плановите и дизајнот на клиентите, а понекогаш и прават нов дизајн од нула. Откако ќе ги одредат најекономичните, најпогодните и најбрзите процеси за одреден проект, формална понуда или предлог се презентира до секој клиент. По заеднички договор на двете страни, и ако проектот е подготвен да се однесе на следното ниво во производниот циклус, една или неколку наши погони се доделени за производство на производот. Сите фабрики се или една од системите за управување со квалитет ISO9001:2000, QS9000, TS16949, ISO13485 или AS9100 сертифицирани и произведуваат производи во согласност со европските и американските индустриски стандарди како што се ASTM, ISO, DIN, IEEE, MIL. Секогаш кога е потребно или потребно, производите се сертифицираат и се ставаат UL и/или CE ознака, или ако се за медицинска примена, тие се придружени со FDA сертификат. Ние поседуваме некои од овие производствени погони и имаме делумна сопственост во некои други. Со некои фабрики и специјализирани производствени претпријатија имаме партнерства или заедничко вложување. Ние, исто така, постојано гледаме на глобално ниво за купување акции или партнерство со нови производствени погони доколку тие ги исполнуваат нашите очекувања. Ова е бескраен циклус кој не тера да се подобруваме и растеме од ден на ден. Низ годините опслужуваме многу клиенти. За да видите што мислат некои од нив за AGS-TECH, ве молиме кликнете на оваа врска. ПРЕТХОДНА СТРАНИЦА

One of AGS-TECH Inc. specialties is Manufacturing Extraordinary Products such as brushes, mesh and wire, filters and filtration products for air & gases, liquids and filtering of solids, tanks and containers, membranes, industrial leather products, specialty textiles. Производство на вонредни производи Под извонредни производи мислиме на оние кои бараат специјализирано знаење, вештини и опрема за производство. На пример, ако ви требаат четки за специјална обработка, и ако производ за четка што се наоѓа надвор од полица не е лесно достапен, ќе треба да разговарате со нас за да се увериме дека нема да трошите парични и временски ресурси обидувајќи се да имате фабрика за калапи развива и произведува четка за вашата апликација. Инженерска фирма или производствен погон што не е специјализиран особено за четки, многу веројатно ќе го троши вашето време и средства и на крајот нема да може да испорача задоволувачки производ. Слично на тоа, ако сакате да се развие и произведе метален резервоар (контејнер) со сопствена големина за вашата процесна опрема, многу работи може да тргнат наопаку ако задачата му ја доделите на обичен производител на лим. Резервоарите треба да бидат направени од вистинскиот материјал, десен манометар, соодветно да се заварат и доработат, а додатоците како што се мерачите на притисок, мерачите на температурата, диспензерите... итн треба да бидат правилно избрани и инсталирани на вистинските локации. Дефинитивно бара соодветна експертиза за да не завршите со опасен резервоар кој може да експлодира или да истече корозивни хемикалии. Типот на извонредни производи развиени и произведени од нас го вклучуваат следново ( Ве молиме кликнете на сино означениот текст подолу за да отидете на соодветната страница ): Филтри и производи за филтрирање и мембрани Четки Мрежа и жица Резервоари и контејнери Индустриски кожни производи Индустриски и специјализирани и функционални текстил Индустриски хемикалии и потрошен материјал ПРЕТХОДНА СТРАНИЦА

Test Equipment for Cookware Testing, Cookware Tester, Cutlery Corrosion Resistance Tester, Strength Test Apparatus for Knives, Forks, Spatulas, Bending Strength Tester for Cookware Handles Тест опрема за тестирање на садови за готвење Специјализирана опрема за тестирање за тестирање на садови за готвење се користи за тестирање на производи за готвење како што се тенџериња, шпорети под притисок итн., за проверка на нивниот квалитет, издржливост, функционалност, доверливост, безбедност, усогласеност со домашните и меѓународните стандарди... итн. . Нашата специјализирана опрема за тестирање може да биде или: - КОРИСТЕНА ДИЗАЈНИРАНА и ПРОИЗВОДЕНА СПЕЦИЈАЛИЗИРАНА ТЕСТ ОПРЕМА за ТЕСТИРАЊЕ НА САДОВИ за готвење или - СПЕЦИЈАЛИЗИРАНА ТЕСТ ОПРЕМА ЗА ТЕСТИРАЊЕ НА САДОВИ Прилагодено дизајнирана специјализирана опрема за тестирање е дизајнирана и развиена од нас за специфичните потреби на нашите клиенти, земајќи ги предвид специфичните барања на нашите клиенти, нивните пазари, нивните законски одговорности... итн. Ние работиме со вас рака под рака за да го постигнете она што ви треба и сакате. Нашите инженери дизајнираат, прототипираат и добиваат ваше одобрение пред да ги направат вашите тест машини. Од друга страна, нашата специјализирана опрема за тестирање за тестирање на садови за готвење се веќе дизајнирани и произведени системи кои можат брзо да се купат од нас и да се користат. Ако ни известите што ви треба, со задоволство ќе ве водиме и ќе ви предложиме подготвени системи кои можат да помогнат во постигнувањето на вашите цели. Нашата специјализирана опрема за тестирање за тестирање на садови за готвење може да се преземе од обоените врски подолу: Каталог на машини за тестирање на садови за готвење Haida За друга слична опрема, посетете ја нашата веб-страница за опрема: http://www.sourceindustrialsupply.com КЛИКНЕТЕ Услуга за пронаоѓање на производи-локатор ПРЕТХОДНА СТРАНИЦА

Holography - Holographic Glass Grating - AGS-TECH Inc. - New Mexico - USA Производство на холографски производи и системи Ние доставуваме залихи на полицата, како и прилагодено дизајнирани и произведени ХОЛОГРАФСКИ ПРОИЗВОДИ, вклучувајќи: • Холограмски дисплеи од 180, 270, 360 степени/ Визуелна проекција базирана на холографија • Самолепливи холограмски дисплеи од 360 степени • 3D филм за прозорци за прикажување реклами • Full HD холограмска изложба и холографски дисплеј 3D пирамида за рекламирање со холографија • 3D холографски дисплеј холокуб за рекламирање со холографија • 3D холографски систем за проекција • Холографски екран со 3D Mesh Screen • Заден проектен филм / Преден проектен филм (со ролна) • Интерактивен екран на допир • Заоблен екран за проекција: Екран за заоблена проекција е приспособен производ направен по нарачка за секој клиент. Ние произведуваме заоблени екрани, екрани за активни и пасивни екрани на 3D симулатори и симулациски дисплеи. • Холографски оптички производи како што се налепници за безбедност и автентичност на производот (прилагодено печатење според барање на клиентот) • Холографски стаклени решетки за украсни или илустративни и едукативни апликации. За да дознаете за нашите можности за инженерство и истражување и развој, ве покануваме да ја посетите нашата инженерска страница http://www.ags-engineering.com КЛИКНЕТЕ Услуга за пронаоѓање на производи-локатор ПРЕТХОДНА СТРАНИЦА