www.hipotsafetytest.com

Chroma launches a comprehensive site dedicated to electrical safety testing and the equipment necessary for safety compliance.

Their hipot and safety equipment will perform the tests you need to move production forward. Chroma dielectric withstanding testers will help you and your production in necessary compliance testing of IEC, UL, TUV, CSA, EN and other standards including IEC 60601-1, UL 2601-1, IEC 950, UL 544, UL 60950, EN 60335, EN 60950, EN 61010, CSA C22.2 No.1010.1, UL 3111, and UL 1950.

View and Purchase the Chroma 19052 Hipot Tester (AC/DC/IR) HERE

Chroma Product Line HERE

Chroma’s 66200 series Power Meters

Lake Mary, FL: Hazards with increased global warming and climate changes have tipped countries to establish regulations and standards for regulating product efficiency performance. As an effective means to reduce carbon footprint and minimize negative impact to the environment, the Eco-design Directive for Energy-using Products (2005/32/EC) came into force August of 2007.

Eco-design Directive establishes a framework under which manufacturers of energy-using products (EuP) will, at the initial design stage, be obliged to increase energy efficiency and reduce the products negative environmental impacts.

Various measurement guidelines and requirements have been defined by the Eco-design Directive including power consumption measurement requirements. Measurement of power of 0.5W or greater shall be made with an uncertainty of less than or equal to 2% at the 95% confidence level and measurements of power less than 0.5W shall be made with an uncertainty of less than or equal to 0.01W at the 95% confidence level. The directive also requires increased measurement information on parameters such as voltage, current, frequency, power, total harmonic distortion, and power factor.

Chroma’s 66200 series Power Meters are fully capable of meeting the measurement requirements required by the EuC directive. Combining the power meter with our standard software specifically designed for the 66200 series, users can easily accomplish the required EUP measurement tasks with little effort. In addition to the 66200 series software,

Chroma also provides Power Efficiency Test software as a more comprehensive measurement solution for meeting eco-design requirements on active power efficiency measurements of external power supplies. Chroma power meters also meet Energy Star requirements and are SPEC accepted measurement devices.  You will find the complete Chroma Power Meter Line at Test Equipment Connection in addition to other great Chroma Products which include: AC and DC Loads, AC Power Sources and Power Supply Testing Equipment.

About Chroma Systems Solutions:

Chroma Systems Solutions, Inc. is the North American business unit of Chroma ATE, the world leader in power testing instruments and systems. With offices and manufacturing facilities located around the globe, Chroma is committed to provide excellence in product, service, and innovation. Chroma Systems Solutions is located in Lake Forest, CA. Please visit www.chromausa.com for more company and product information or call us at (949) 600-6400.

About Test Equipment Connection Corporation:

Test Equipment Connection Corp., Test Equipment Connection Pte. Ltd., and TE Connection Asia Limited are industry-leading suppliers of new, refurbished and second-hand electronic test and measurement (“T&M”) equipment. The companies sell, buy, lease, rent, trade, repair and calibrate over 315 manufacturers including Anritsu, Rohde & Schwarz, Agilent, Tektronix, Advantest, LeCroy, Chroma and Fluke, with thousands of products available. The companies are a single source supplier with in-house calibration laboratories assuring that customers receive only the highest quality T&M equipment and support. Test Equipment Connection Corporation has over 250,000 customers, a 45,000 square foot warehouse and repair facility in the US, and 16 years of profitability and financial strength.

Download the Chroma-66200-Power-Meter-Press-Release.pdf

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Press Release Contact Information:

Test Equipment Connection Corporation
30 Skyline Drive
Lake Mary, FL 32746 USA
Voice (800) 615-8378

Test Equipment Connection Pte. Ltd.
6 Battery Road
#31-00 Standard Chartered Bank Building
Singapore 049909
Voice: 65-6320-8596

TE Connection Asia, Ltd.
Unit 13, 16 / FL Fotan Industrial Centre
26-28 Au Pui Wan Street
Fotan Shatin N.T. Hong Kong
Voice: 852-2690-1360
(CHINA): 86 136-3217-2095

Lake Mary, FL USA – Chroma Systems Solutions,  Inc., internationally known for it’s AC and DC Loads,  AC Power Sources and power supply testing equipment, has today joined  forces with Test Equipment Connection through a worldwide distribution  agreement.

Test Equipment Connection, the global single source supplier of general purpose electronic test equipment, will distribute Chroma power products including AC and DC loads, programmable AC Power sources, DC power supplies and digital multi / power meters. “Chroma is a world leader in power test instruments and systems,” commented Mike Novello President and COO of Test Equipment Connection. “Our customers are upgrading to new Chroma AC and DC power supplies after learning about the Chroma brand. Chroma delivers precise high power testing at a great price.”

About Test Equipment Connection Corporation:

Test Equipment Connection Corporation and TE Connection Asia Limited are industry-leading suppliers of new, refurbished and second-hand electronic test and measurement (“T&M”) equipment. They sell, rent, lease, buy, trade, repair and calibrate over 315 manufacturers with thousands of products available new and refurbished. The companies are a single source supplier with in-house calibration laboratories assuring that customers receive only the highest quality T&M equipment and support. Test Equipment Connection Corporation has over 250,000 customers, a 45,000 square foot warehouse and repair facility in the US, and 16 years of profitability and financial strength. Visit www.TestEquipmentConnection.com for more information or call (800) 615-8378 or (407) 804-1299.

About Chroma Systems Solutions:

Chroma is the largest worldwide provider of power testing instruments and systems including programmable AC Power Sources and DC Power Supplies, AC Loads and DC Electronic Loads, Digital Power Meters, Multi-Meters, and Automated Power Supply Testing Systems.  Chroma’s programmable power supplies, electronic loads, measurement instruments and automated testing systems provide solutions for applications in aerospace, defense, military, automotive, medical, battery, solar, marine, and regulatory testing.  Customized systems and instrumentation for power supply test and characterization include architecture and platforms built to fit diverse bench-top, R&D, design verification and automated test system technical requirements and specifications. Applications include testing of batteries and battery chargers, grid inverters, solar panels/arrays, DC-DC & off-line power supplies, fuel cells, photovoltaic arrays and many other related products. With offices and manufacturing facilities located worldwide, Chroma is renowned for it’s commitment to excellence in product, service, and innovation. Chroma Systems Solutions, Inc. is located in Lake Forest, CA. For more company and product information visit their website at www.ChromaUSA.com or call (949) 600-6400.

]]> http://blog.testequipmentconnection.com/test-equipment-connection-signs-distribution-agreement-with-chroma-systems-solutions-inc/feed 0 http://blog.testequipmentconnection.com/zero-ohm-load http://blog.testequipmentconnection.com/zero-ohm-load#comments Wed, 23 Sep 2009 14:41:17 +0000 http://blog.testequipmentconnection.com/?p=403 Read More →]]> In Search of the Zero-Ohm Load

High-wattage resistors often are used as test loads for power transformers. Resistors don’t introduce phase shifts, and it’s easy to check that a transformer’s voltage regulation remains within spec at different rms currents. The effect of various primary tap and secondary loading combinations also can be measured. On the other hand, actual loads don’t always have a constant resistance (CR) characteristic.

Many switching power supplies present a constant power (CP) load to the AC input. DC power supply outputs are intended to provide a constant voltage (CV) or constant current (CC) depending on the mode selected. To simulate anything other than simple CR, you need an electronic load.

Both AC and DC electronic loads are commercially available with DC loads being more prevalent. Either type can emulate a short circuit as well as the CC, CV, CR, and CP modes of operation. According to Adrian Butoi, western regional manager at NH Research, AC loads are used for test applications that require linear or nonlinear AC loading with power and crest-factor control. In addition to the five basic modes of operation, the company’s Model 4600 AC Load also provides unity power-factor loading and a complex nonlinear waveform mode.

Built-in measurements include frequency, voltage, peak voltage, current, peak current, crest factor, apparent power, true power, peak power, reactive power, power factor, and resistance. DC load measurements compose a subset of this list that is not related to reactance.

Cliff Nazelli, the managing director of marketing and sales at PPM Instruments, described a couple of typical applications. In one example, vehicle electrical-system power-distribution module testing must simulate various load conditions. While the module’s durability and temperature rise are monitored, the load current is switched on and off. In another test, fuel-cell impedance is measured by modulating the DC load current. The impedance is determined from the current and voltage amplitudes and their phase relationship.

Isolation also is critical in many cases, especially those that involve off-ground differential voltage sources. Multitap battery load testing is an application that requires this capability.

DC Load Basics

Typically, MOSFETs are used as the dissipating devices in a DC load. These semiconductors have ON resistance much less than 100 mΩ, and several are operated in parallel to achieve the needed power rating. Of course, paralleling devices also reduces the resistance the load presents.

ON resistance is higher for high-voltage MOSFETS than for low-voltage devices, so DC loads rated for 500 V generally will have higher resistance than 50-V loads even if the same number of MOSFETS is used. Figure 1 shows this effect for a 5-kW PPM 600-V load (dark green curve) compared to a 5-kW 60-V load (red curve). The initial slope of the PPM Modular Electronic Load (Mel) 5000-200-600 is 30 mΩ compared to the 1-mΩ resistance of the Mel 5000-600-60 even though there is only a 3:1 ratio relating their maximum currents. The resistances of the lower wattage Chroma loads range from 5 mΩ to 25 mΩ.

Figure 1. Safe Operating Areas for Various DC Loads
Source: Chroma Systems Solutions and PPM Instruments

All electronic loads have a safe operating area (SOA) limited by voltage, current, and power. These areas are indicated in Figure 1 for the PPM Mel 5000-600-60. As the input current increases, the voltage across the load also increases because of the load’s finite resistance. At the maximum current, higher voltages can be supported but only to the maximum voltage and power ratings.

On a graph with linear X- and Y-axis scaling, the maximum power curve is a hyperbola. The load voltage can continue to increase to the maximum voltage limit as long as the current is low enough that the maximum power limit isn’t exceeded. As the figure shows, the SOAs of loads having the same power limit are bounded by the same hyperbolic curve although it may be intersected at different places by the voltage and current limits.

It’s also important to note the lack of standardization regarding load specification in datasheets. The NH Research Model 4750 DC Load and PPM Mel Series show the SOA on a graph with voltage plotted vertically and current horizontally on a log-log grid. Chroma’s 63600 Series datasheet plots this information with the same axes but on a linear grid.

Several manufacturers’ graphs showing low-voltage characteristics generally have linear grids with current plotted vertically and voltage horizontally. Of course, depending on the DUT, current or voltage could be the independent variable, so it really doesn’t matter how the graphs are drawn as long as you understand what they mean.

Finally, model numbers may include power, voltage, and current limits but not always in the same order. PPM’s Mel Series lists power, current, and voltage: Model 5000-200-600 is a 5-kW load with 200-A and 600-V maximum limits. Chroma’s Model 63630-80-60 is a 300-W unit with 80 V and 60-A capabilities.

DC Load Selection

You must choose a load with an SOA sufficient to handle the maximum current, voltage, and power expected from the DUT. The actual combination of current and voltage can lie anywhere within the SOA. Nevertheless, the trend in semiconductors is toward low voltage and high current so supporting this combination often is a major consideration.

Jim Dougherty, senior engineer at Chroma Systems Solutions, explained, “Up to a maximum current limit, a DC load presents a constant minimum resistance. For example, if a load can support a 10-A current and has a 10-mΩ resistance, the DUT output voltage must be at least 100 mV even if the connections and wiring were perfect. Taking into account the finite resistance of the connections and wiring further increases the minimum DUT output voltage required for the load to sink the full current. Of course, the load can be programmed to represent a higher resistance but you cannot get less than the minimum.

“Suppose you have designed and characterized your DUT interconnect and cable resistance and found that RSeries = 2 mΩ. Further, assume you need to support 0.5 V @ 60 A. To do this,” he continued, “the DC load must represent a resistance RLoad <(0.5/60)-0.002 or RLoad <~6 mΩ. The sloping lines in Figure 2 show the resistance associated with three models of Chroma 63600 Series Loads and correspond to the area circled in Figure 1. As expected, the higher the output current rating, the lower the resistance. And, loads can be operated in parallel to achieve higher current capacity as well as lower resistance.”

Figure 2. Low-Voltage Resistance Characteristics of DC Loads
Courtesy of Chroma Systems Solutions

Zero-Volt Operation
What if you need to sink the full rated current but the voltage drop associated with the load resistance and wiring is large compared to the DUT output voltage? Adding a boost supply in series with the load effectively increases the DUT output voltage and makes possible even zero-volt full current loading.

However, Mr. Dougherty cautioned, “Boost supplies should be considered only as a last resort. The effective power of the load that otherwise would be available to the DUT is reduced; you no longer can perform transient tests; noise from the supply affects ripple and noise measurements; and complexity and cost are increased.”

Commenting on his company’s true zero-volt PLZ-4WA Series of DC loads, Takuya Takeda, vice president of Kikusui America, said, “The PLZ-4WA employs a bias supply installed directly in the electronic load. It supports true zero-volt operation by stepping up the input voltage and applying a load voltage adequate to allow the internal current source to operate correctly.

“A switched-mode power supply is small enough to fit inside the load,” he continued. “Typically, a switched-mode supply can create noise issues, but that is not the case with this bias supply. It has been designed using zero-volt switching technology and other special techniques to reduce noise.”

An extensive feature set has developed around the basic DC load function to address a wide range of applications. Four-wire Kelvin connections ensure that the DUT terminal voltage is used in power calculations, not the load voltage that is reduced by wiring and connection IR drops. Also, because many tests require switching the load on and off to stimulate DUT transient response, this aspect of DC load design has become very sophisticated.

Transient Response
A DC load’s internal wiring and terminations must present a low impedance, not just a low resistance. Mr. Nazelli explained that PPM uses a heavy-duty laminated copper bus structure internally in conjunction with a proprietary FET circuit board layout to ensure the lowest possible impedance. In particular, the laminated copper bus minimizes the impedance increase caused by skin effect that otherwise would occur at high frequencies.

The depth at which AC current density has been reduced to 37% of its value at the conductor surface is given by

where: δ = skin effect depth
ρ = conductor resistivity
ω = 2πf
µ = conductor absolute magnetic permeability

For a copper conductor, skin depth varies from more than 8 mm at 60 Hz to only 66 µm at 1 MHz. Engineers have used Litz wire for many years to minimize the resistance increase caused by skin effect. Litz wire is stranded, but each strand also is insulated. A laminated bus achieves a similar result in a form that may be more easily manufactured and terminated, especially for high current levels.

The PPM Mel units are specified with a 15-µs to 20-ms rise time, selectable in 36 discrete steps, and a DC to 10-kHz frequency response. A 600-A load has a maximum slew rate of 600/15 or 40 A/µs. When loads are connected in parallel, the slew rates add. On the other hand, the highest practical slew rate is limited by the inductance of the wiring needed to connect the loads in parallel.

Kikusui’s Model PLZ1004W is a 1-kW load with a maximum current rating of 200 A and a slew rate of 16 A/µs. For the PLZ-4W Series, the slew rate is variable over a 100:1 speed ratio and guaranteed to be accurate to within 10% for current within 2% to 100% of rated value. This series also supports frequency range selection.

According to Kikusui’s Mr. Takeda, “Dynamic response only is required for transient response tests of power supplies. A wide bandwidth isn’t necessary for static tests such as load variation tests and foldback characteristic tests. Excess bandwidth affects load stability so the PLZ-4W/4WA load includes selectable bandwidth, and it can be optimized to match the kind of test and test condition.”

NH Research’s Mr. Butoi explained that because the load manufacturer cannot control DUT and cable inductance, the most straightforward solution to mitigate voltage spikes, ringing, and oscillation is to allow load-current slew-rate programmability. Usually, slowing this slew rate eliminates the problems.

PPM provides two types of filtering as discussed by Mr. Nazelli, “The architecture of the Mel employs a control board with programmable loop response to vary the control-loop speed where you need to adjust rise/fall times for pulse tests and stimulus/response testing. This is one type of filtering. Separately, filtering is used on the FET circuit board assemblies to control the feedback loop response of the power-dissipating devices. The operator can adjust the loops to shape the response either to further control rise/fall times or eliminate oscillations induced from external reactive components.”

Power to the Load

Regardless of the other characteristics a DC load may have, it must dissipate power-sometimes a lot of power. The products in PPM’s Mel Series can handle 1 kW to 5 kW, and master-slave configurations up to 80 kW are standard. Eight models in NH Research’s 4700 Series range in capacity from 1 kW to 36 kW. Chroma’s Series 63200 High Power DC Loads are available in sizes from 2.6 kW to 15.6 kW. These three load series are air-cooled.

Most manufacturers of heavy-duty loads support paralleling for higher power handling. Loads feature individual device protection against over-temperature, over-voltage, and over-current conditions and further ensure performance through active current balancing. For larger power ratings, master-slave systems usually are rack mounted and up to 6 ft high.

One alternative to a big air-cooled unit is a water-cooled unit. AMREL’s PLW Series handles up to 250 kW, and several versions of the 36-kW model are available in a 4U-high x 27.5″ deep rack-mount size. As a comparison, a 5-kW AMREL Series PLA Air-Cooled Load is approximately the same size.

Another solution appropriate for high-power applications is Kikusui’s Model PLZ6000R Regenerative DC Electronic Load. The basic unit acts as a 6-kW load although only about 15% of this is dissipated. The rest of the power is regenerated as a synchronous AC current fed back into the AC mains. Up to five units can be combined in a master-slave system to provide a 30-kW capacity.

Several ranges of benchtop DC loads also are available with ratings to a few hundred watts. Three models from Chroma’s 63600 Series are shown in Figures 1 and 2. B&K Precision’s 150-W Model 8540 handles up to 60 V and 30 A in the CC, CR, and CV modes with current, voltage, and power measurements presented on an integral display. Model 8510 has a 600-W capacity with 120-V and 120-A limits. It, too, provides an integral display and includes a CP mode as well as battery test capability.

Kikusui’s PLZ-4W Series features 165-W, 300-W, 660-W, and 1-kW models. In addition to the basic products, the 165-WA and 660-WA models are available with a built-in bias supply and support true zero-volt operation.

The 300-W Model LD300 DC Load manufactured by Thurlby Thandar Instruments and available in the United States from Saelig has 80-V and 80-A maximum ratings. It supports the CC, CV, CR, and CP modes and provides a transient generator, a variable slew rate, soft start, and a current monitor output.

Controlling the Power
In addition to a load’s fundamental capabilities, the extra features it offers can be important depending on the types of tests you need to run. Kikusui’s PLZ-4W Series includes soft start, a variable slew rate, a switching function, a preset memory function, 100 setup memories, and a sequence function.

B&K Precision’s 8500 Series Loads also support battery testing by measuring total battery discharge in amp-hours. Jeremy Lo, an application engineer at the company, said, “Software is available to control the load for this test. It plots battery discharge curves in real time as well as gives you the option to export raw data in text or Excel format for further analysis. The software also can be used to monitor and plot power, voltage, and current levels at the load inputs.”

In NH Research’s Model 4700 DC Electronic Load, an auto mode provides glitchless switching among the CR, CC, CV, and CP limits. Further, you can programmatically control the mode of operation and its duration via a 100-step customizable macro with 10-µs timing resolution.

PPM’s Mel Loads have several means of control. RS-422 and USB 2.0 ports are standard with both GPIB and Ethernet optionally available. You can log into a load’s IP address to perform remote control and diagnostics. According to Mr. Nazelli, “This also enables PPM to send feature improvements without hardware intervention and without requiring you to return units to PPM. In addition, you can add modules in the field to upgrade a load. The load automatically reconfigures itself to its new capabilities.”

Chroma’s Model 63472 High Slew Rate DC Load incorporates Intel’s power test tool (PTT), which can simulate microprocessor load changes of up to 150 A at a 1,000-A/µs slew rate. Because the PTT is small enough to fit into a microprocessor socket, it cannot dissipate the required power without significantly changing its temperature and operating characteristics. The 63472 provides measurement hardware and over-current and over-voltage protection as well as the automatic calibration required to ensure test-result accuracy.

Unless you use a device such as the PTT, there’s no way to connect a high slew-rate load that will not introduce significant errors. The PTT mimics the load presented by a microprocessor, which may have 100 or more power and ground pins. The slew rate at each pin is only a few amps/µs, and most of the transient current is provided by local capacitors. With the PTT, you are testing the capability of the power supply in combination with local capacitors to cope with the overall 150-A changes and 1,000-A/µs slew rate.

Summary

Many models of DC electronic loads are available, some with very specialized capabilities. Determining the load that will best fit your test requirements starts with a list of the specifications you must have. Power dissipation, maximum current and voltage, and the minimum resistance the load presents are key to most applications. So, too, are the modes in which you will operate the load and how it changes from one to another.

(Source Tom Lecklider –  Evaluation Engineering http://www.evaluationengineering.com/features/2009_september/0909_electronic.aspx )

Chroma Systems Solutions 61500 Series High-power AC power source 12K VA – 18 KVA

• 1 – 3 Phase

• Highest performance ACS source with power analyzer functions built-in

• Provides 0-300 VAC or 0-424VDC output from a single source

• Built-in DSP provides for voltage transient simulations, harmonic current measurements and compliance testing to many IEC and military standards

Chroma 61500/61600 series are able to provide precision measurements such as RMS voltage, RMS current, true power, power factor, current crest factor and so on. By applying the advanced DSP technology, model 61511/61512 can measure THD and up to 40 orders of current harmonic components. And 61511/61512 can easily simulate power line disturbance  (PLD) by LIST, PULSE and STEP modes. They also allow users to compose different harmonic components to synthesize their own harmonic distorted wave-shapes. Besides that, users can program a sweeping frequency component incorporate with fundamental voltage to find the resonance points of UUT. To simulate the natural waveform, the 61500 series also provides an external analog input to amplify the analog signal from arbitrary signal generator. Thus, it is capable of simulating the unique waveform observed in the field.