Power Electronic Tips

Power supply offered in 85 – 265 V AC single-phase input option

Redding Traiger — Wed, 11 Sep 2024 16:51:46 +0000

TDK Corporation introduces the HWS3000 programmable AC-DC power supplies in the TDK-Lambda series. These units deliver up to 3000 watts in a 270 x 150 x 61mm case size. The HWS3000 offers programmable output voltages of 24V, 48V, 60V, or 130V, with the ability to adjust from zero to maximum rating. Engineers can choose between 85-265Vac single-phase or 170-265Vac three-phase input options, providing flexibility for various power environments.

Programming capabilities include an RS485 interface with MODBus protocol, as well as analog 1-5V or 4-20mA signals. The power supplies feature a variable speed fan with 45dB noise at less than 70% load and 25°C ambient temperature. With an efficiency of up to 93%, the HWS3000 series minimizes heat generation, contributing to its compact design.

The HWS3000 operates in temperatures ranging from -20°C to +70°C, with start-up capability at -40°C. It provides robust isolation, with 3000Vac input to output, 2000Vac input to ground, and 1500Vac output to ground. The power supplies maintain a low leakage current of less than 0.85mA and can function at altitudes up to 5000m (2000m for IEC/EN62477-1 standard compliance).

Engineers will appreciate the scalability of the HWS3000, allowing up to 3 units in series or 10 in parallel. The series includes additional features such as a 5V 2A standby voltage, remote on/off functionality, remote sense, and fan fail and power good signals. Output terminals are configurable for horizontal or vertical connections, enhancing installation flexibility. Digital monitoring capabilities include voltage slew rate control, cumulative operating time tracking, fault logging, and product identification information.

The HWS3000 series meets a range of safety certifications and EMC standards, including IEC/EN/UL 62368-1, IEC/EN62477-1, EN55032A, EN55011-A, FCC-A, EN 61000-3-2, and IEC 61000-4. This compliance ensures the power supplies are suitable for use in various industries and applications. TDK Corporation backs these power supplies with an extended 5-year warranty, providing engineers with long-term reliability assurance.

These versatile power supplies are well-suited for applications in test and measurement, semiconductor fabrication, RF amplifiers, laser machining, printing, and various industrial equipment. The combination of high power output, compact design, and flexible programming options makes the HWS3000 series a valuable tool for engineers working on diverse power supply challenges.

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Single-phase EMI filters for AC and DC applications

Redding Traiger — Tue, 23 Jan 2024 18:30:05 +0000

TDK Corporation has expanded its portfolio of single-phase EMC filters with the B84742A*R725 series. These components serve AC as well as DC applications up to 250 V and rated currents from 6 A to 30 A. This means they can be used for increasingly popular DC infrastructure in the industrial and building sectors. Available in five versions, the 97 x 60 x 34.5 mm (L x W x H) small single-phase filters, weighing no more than 310 g, can be snapped quickly and conveniently onto the TH35 DIN rail, also known as a top-hat rail. The conductors are fastened with M4 screws, and the screw connection is equipped with touch protection.

Particularly, the insertion loss of the filters is very high: Depending on the model, this is 40 dB for common mode and over 80 dB for differential mode noise at frequencies between 70 kHz and 10 MHz. At the same time, leakage currents are very low at less than 2 mA, which prevents unintentional tripping of RCDs. All types of this product family are UL-approved and specified for a rated temperature of up to 55 °C.

For short periods of time, the EMC filters can handle higher currents; 150% of the rated current is allowed for three minutes per hour and even 250% for 30 seconds per hour. This is particularly useful in drive applications when starting electric motors. Other typical applications are power supplies as well as ICT.

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Calculations reveal the value of efficiency

Chris Harman — Tue, 27 Sep 2022 15:06:51 +0000

A few back-of-the-envelope estimates show why it pays to maximize power supply efficiency.

Chris Harman • Puls l.p.
Engineers are becoming more sensitive to efficiency when selecting a power supply. Energy flows through the supply, and something less than 100% of that energy can be used because of inefficiencies of power supply components. The difference between usable energy and wasted energy is dissipated as heat. Heat is the enemy because it degrades the components in the power supply and other components in the electrical enclosure.

Suppose we have two power supplies, one 92% efficient, the other 96%. Both sound relatively efficient. Using these figures, we might think that the difference is only 4% (96% – 92% = 4%). But if we have a 100-W power supply, the 92% efficient power supply loses 8 W and the 96% efficient power supply loses 4 W. That is 50% less heat loss from the 96% efficient power supply.

Let’s look at a real-world example using two 480-W power supplies. The PULS CP20.241 has an efficiency rating of 95.6%. A competitive unit recently released has an efficiency rating of 93.1%. The apparent difference is 2.5%. At first glance, not a big deal. But as with the previous hypothetical example, the percentages hide a significant difference in energy use. A 95.6% efficient supply loses 21 W mainly to heat, while a 93.1% efficient supply loses 33 W, or about 57% more.

A simple method to determine the true difference of heat loss when comparing power supplies is to use the heat loss formula:

Heat is the number one enemy for power supplies because they normally use electrolytic capacitors. Electrolytics have a reputation for exhibiting a short service life when heat is a factor. The most common reason for reduced electrolytic capacitor lifespan is the evaporation or leakage of the liquid electrolyte. Environmental and electrical factors also play a role. Typical environmental factors that can shorten capacitor life include humidity, high temperature, mechanical vibrations, and humidity. Electrical parameters such as applied voltage, charge-discharge duty cycle, and ripple current can also lead to premature failure.

In the thermal image, the larger blue circle at the bottom, and the three smaller blue circles in the upper right are capacitors. those capacitors are positioned so either they reside in a naturally cooler area (bottom), or they are separated by an air channel that protects them from heat and therefore extends their lifetime and boosts their reliability.

Datasheets define electrolytic capacitor service life under a nominal voltage, nominal current, and upper temperature limit . The temperature, ripple current, and apple voltage can accelerate aging. High temperature speeds the aging of electrolytic capacitors because it boosts the chemical reaction rate. A rise in temperature leads to the gradual evaporation of the electrolyte through the seal.

The life expectancy of an electrolytic capacitor is influenced by the applied voltage as well as the reverse voltage across the cap. Application of excessive voltage across the electrolytic capacitor boosts leakage current. The leakage current is responsible for internal gas generation and self-heating in the capacitor, which ultimately damages the capacitor’s internal structure. Reverse voltage above a few volts causes internal heating and pressure. If an electrolytic capacitor sees high reverse voltage, it may fail from the opening of the safety vent.

Ripple current through an electrolytic capacitor produces more internal heat. Discharge currents are catastrophic to electrolytic capacitor lifespans. The discharge current increases the internal heating and pressure, which reflects as the capacitance value drop during initial stages. With time, the charge-discharge duty cycle may lead to the destruction of the electrolytic capacitor by opening the safety vent to release gases.

The general rule of thumb, as published by capacitor manufacturers, is that every 10°C increase in temperature results in a 50% decrease in life for the capacitor. Since capacitors are so sensitive to heat, a good design will also thermally separate the capacitors from heat producing components like transformers and bridge rectifiers.

In addition to the drawbacks of electrolytic capacitors, often there are far more sensitive electronic components inside an enclosure which can be degraded by heat. In a nutshell, heat can radically reduce the reliability and lifetime of the power supply and other components in the enclosure. In many cases, it can force the use of a larger enclosure, the use of a cooling, or a derating of equipment to compensate for high heat losses.

Thus a power supply with the highest efficiency and good thermal design can mean the difference between a reliable control system and a system where problems ultimately will surface.

Design engineers must also consider the amount of energy necessary to operate the load. Referring to the example of the two 480-W power supplies, we can review them from an energy standpoint. The power supply which was rated 93.1% efficient and had 33 W of lost energy would, from a simplistic calculation, lose 1.65 kW over a 50-hr work week. The 95.6% efficient CP20 supply would have losses of only 1.05 kW. Using an average cost of 13¢/kWh. Thus the less efficient supply would waste approximately $11.16 annually vs. $7.10 annually for the CP20. Multiply this by the number of power supplies in use and the savings can be quite significant over the life of a control system.

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