CCM, A Family Of Magnetic Components Dedicated To Space Applications and Optimized For Multi-output Flyback Converters
Présentation SPCD 2022 14 October 2022 ESA/ESTEC, Noordwijk, The Netherlands Bruno Cogitore (EXXELIA R&D Center, 137 rue de Mayoussard, ZA de Centr’Alp, 38430 Moirans, France. bruno.cogitore@exxelia.com) Jean PIERRE (EXXELIA SAS, 16 parc d’activités du Beau Vallon, 57970 Illange, France. jean...
INTRODUCTION
In the mid-2010s, EXXELIA decided to develop a family of Magnetic Components products capable of withstanding the harsh environments of aerospace and especially space, and complementary to existing SESI and TT families. Exxelia decided to develop Chameleon Concept Magnetics (CCM).
The range currently consists of 5 sizes, CCM4/5/6 and CCM20/25. The maximum transferable power in the CCM25 is about 200W, depending on the operating conditions of the transformer. A CCM30 is currently under development. This would approach 350W. The internal construction of the CCMs is similar to that of the SESIs, but there are some differences. Exxelia wanted to optimize the reproducibility of the electrical characteristics. Exxelia defined sizes with many connections, to focus on multi-output applications. CCMs are more compact and higher than SESIs. Today, the raw materials used all have a thermal class of 180°C.
Figure 1: Overview of the current CCM range
PART 1: SPATIAL QUALIFICATION WITH ESA/CNES
The qualification of SESI concerned standard ranges of QPL differential mode chokes and common mode chokes. Over the years, Exxelia has seen more and more developments of specific, so non-QPL products. In these cases, the technology used was space compatible, as the inductors were space compliant and the raw materials and manufacturing process were almost identical. However, these products did not have QPL status.
For the 5 sizes of the CCM family, Exxelia chose to do things differently in order to have a valid qualification for all types of functions, inductors, and transformers. Exxelia chose to apply for and pass a Technology Know-How Approval (TKA), which has since become Technology Flow (TF).
The principle of TF is to define precisely the technology with which products will be manufactured, associate to it design rules with it, evaluate the technology, and then qualify it. Once the TF is obtained, any product that meets the technology and design rules has the status of qualified and can be used without further testing. This saves money and time.
The TF consists of two successive phases whose objective is to demonstrate the reliability of the technology with respect to all the constraints that the component will have to undergo during its life. The first phase is the evaluation phase, the second is the qualification phase.
The evaluation phase is the most important one, as it is the one that must show the robustness of the technology in all stress domains. It is on the initiative of EXXELIA. The qualification, supervised by CNES and ESA, only confirms the compatibility of the technology with the space environment on a limited number of tests and components representative of the whole range of sizes.
Before starting the tests, EXXELIA defined the framework of the CCM technology, i.e. two detailed and exhaustive lists, one for the raw materials and one for the manufacturing operations. With regard to raw materials, all categories were well-defined:
Magnetic circuits / cores : manufacturer(s) and material(s),
Bobbins: dimensions and materials,
Winding wires: manufacturer(s), grade of insulating enamel, thermal class, and diameters,
Solid insulators: manufacturers and materials,
Glues, resins and varnishes: manufacturer(s) and references,
Solderings and fluxes,
ESD packagings.
With regard to manufacturing, all operations from winding to the packaging were also detailed. Thus, with these two lists, the framework for CCM technology is perfectly clear.
In addition to these manufacturing constraints, EXXELIA defined a quality framework including working methods, documents, and a level of traceability compliant with space requirements.
For the evaluation phase, a large number of tests were planned and carried out in the following areas: thermal shocks, burn-in, life test, dielectric strength, internal component heating (Rth), shock and vibration mechanical resistance, brazing and soldering heat resistance, solderability, pin pull-out strength, marking resistance, and moisture resistance. In each area, a test procedure has been defined as well as the number of components involved. The ESCC3201 standard, which itself is based on several MIL standards, was used as a guide throughout the evaluation campaign, which took much time. Several hundred parts were manufactured, tested, and even destroyed. In fact, in several areas, Exxelia pushed the components beyond their limits in order to determine the safety margins available to Exxelia. In all aspects, particularly thermal, mechanical and long-term reliability, Exxelia has found that they are sufficient for the needs of space.
This evaluation campaign was a success. It was the subject of a report [1] sent to ESA. The qualification phase then took over. It too was a success. A complementary document was created to follow the qualification evolutions of this technological family.
Exxelia now had a space-qualified technology family that allowed Exxelia to design a wide range of components for customers' applications.
Exxelia now needed to know in detail how components would behave in the customer's environment.
PART 2: THERMAL, FREQUENCY, AND SATURATION BEHAVIOURS
In order for customers to choose the right component for their application, Exxelia needs to provide them with a set of information on the behavior of components. Exxelia, therefore, decided to carry out three characterization campaigns: thermal, frequency, and saturation.
THERMAL CHARACTERISATION
Internal heating of components is becoming an increasingly important aspect, taking into account the increase in the ratio of power by weight and power by volume in equipment. EXXELIA has therefore launched several actions in this field. One of them is to improve knowledge of the thermal behavior of two of its standard component families, CCMs and TTs. During the qualification of CCMs, a campaign had already been carried out in this field. The results were neither sufficiently precise nor sufficiently complete to meet the needs for information and advice to customers. Ideally, mathematical models of thermal resistance in a vacuum or measurements in a vacuum should have been available quickly. Both of these are possible, but they are very time-consuming because the mathematical study involves the physics of fluid mechanics, and making thermal measurements in a vacuum is complex. As a first step, Exxelia decided to carry out a characterization campaign with natural convection in air, which will serve as a reference for the ongoing studies in a vacuum. Conduction and radiation, which play a significant role in calorie extraction, are indeed present in both air and vacuum.
In addition to the dependence on component characteristics, Rths vary according to several external parameters, in particular :
Ambient temperature,
Environment (carrier PCB/other, air/vacuum, horizontal/vertical layout, and so on),
Power level to be dissipated in the component, i.e. the losses,
The location of these losses is in the windings (copper), or in the magnetic circuit (iron core).
EXXELIA has already carried out this type of experimental characterization in the 2000s for the SESI family of components. The objective of this study was to carry out the same work on the CCM and TT families. Exxelia only details the CCM part.
The components are SMD. They are single-winding inductors. For simplicity of calculation of the losses, and sources of heating, Exxelia chose to supply the inductors with direct current. The component winding resistances are between 5mΩ and 2Ω at room temperature. The excitation conditions are such that the maximum temperature rises bring the components to a temperature of about 180℃, which is the thermal class of all raw materials used in CCMs.
The temperature of the component is measured via the winding resistance measurement. The law of variation of copper conductivity with temperature is taken into account and it is assumed that the temperature gradient in the different parts of the component, molding and magnetic circuit, is small compared to the overall rise in ambient temperature. The component is supplied for a sufficient time to reach the stabilized thermal steady state.
For each size, Rth measurements are made at six different ambient temperatures: 25, 50, 75, 100, 125, and 150℃. For each ambient temperature, Exxelia first determines the PowerPoint that brings the component to around 180℃. For the curve at 25℃ambient temperature, fifteen measurements of Rth are made at injected powers equally distributed between 0 and the maximum power determined previously. For the curves at higher ambient temperatures, the same power points are used, except those leading to maximum temperatures above 180℃. Two inductance values are characterized for each of the 5 sizes, i.e. 10 components to be tested.
All components are soldered onto a PCB similar to that used for SESI characterization. The temperature of the PCB is measured throughout the tests to identify any increase in temperature.
A 112-liter ventilated oven was used. Care was taken to protect the components from ventilation inside a box. The box was defined that was large enough in comparison to the volume of the largest component to be characterized. It was perforated at the top and bottom to allow natural convection between the box and the ventilated airflow outside. The temperature inside the box was measured to identify any rise in its average temperature.
Exxelia is not going to detail the development of the experimental bench here, but it was an important part of the work. In particular, Exxelia analyzed in detail the study and the setting up of the box inside the oven, the monitoring of the different temperatures as well as all the metrology used, in particular the accuracy of the results. Exxelia also made comparative measurements at 22°C inside the oven and outside in order to verify that the oven had a sufficiently small influence on the results. Figure 2 below shows the synoptic of the bench.
Figure 2: Synoptic diagram of the test bench
Figure 3 below shows an example of the curve obtained for a CCM20 6K8. The Rth values on the y-axis have been removed.
Figure 3: Rth in air versus power dissipation curves for a CCM20 6K8
Once all the curves were obtained, several checks were made, firstly on the shape of a curve. The Rth decreases with the power dissipated and also with the ambient temperature, which seems to be consistent with the laws of thermic. Exxelia also compared the curves from one size to another. Exxelia is convinced that the curves obtained are close to the reality of the thermal behavior of the component placed in this environment. It should be remembered that the role of the environment is fundamental. A provisional conclusion of all the actions underway in this thermal project is that a component has as many Rth as the environments in which it is placed.
As mentioned above, these curves for natural convection in the air are to be considered as a reference. Characterization in a vacuum and the construction of a mathematical model of the thermal resistances of CCMs are underway. The results should be available in 2023.
FREQUENCY CHARACTERIZATION
It was concretely a question of drawing for each selected component an inductance curve as a function of frequency under constant excitation at room temperature
For each of the 5 sizes, 3 different inductance values are characterized. The 2 values already thermally characterized are chosen, plus one whose value is between the 2 previous ones. The inductances are measured with a device with an accuracy of between 0.5 and 2% depending on the measurement conditions. All components are soldered to the same PCB used for thermal characterization. For new components, the same type of PCB is used.
All the components are powered under constant induction, so at a constant V/F ratio. Exxelia has chosen a sine excitation voltage of 10mVrms at 10kHz. This corresponds to a voltage of 10Vrms at 10MHz, the maximum defined frequency. The corresponding induction level varies according to the iron section of the size but is on average a few hundred µT, which corresponds to the order of magnitude with which Ferrite manufacturers, Ferroxcube for example, characterize the permeabilities of their circuits. For each component in each size, L is measured at 15 different frequencies distributed logarithmically between 10kHz and 10MHz, i.e. 5 measurement points per decade. In some cases, the component resonates before 10MHz. In this case, Exxelia limits itself to this resonance frequency. In other cases, when the impedance variations are important, this point distribution has been modified to better take these variations into account.
Figure 4 below shows two example results, for the CCM5 3.3µH and the CCM20 6.8µH. This is the series imaginary part of impedance Ls calculated via an impedance analyzer.
Figure 4: Series imaginary part Ls of the impedance of CCM5 3K3 and CCM20 6K8 inductors
It can be seen that the resonant frequencies are around 10MHz, which is logical since, as the inductance values are low, so are the numbers of turns and the parasitic capacitances. These inductors can therefore be used at frequencies well above 500kHz.
SATURATION CHARACTERIZATION
It was concretely a question of drawing for each selected component two inductance curves as a function of excitation current, under DC+AC current, one at 25°C ambient, the other at 125°C, since the saturation induction Bsat decreases with temperature.
The components tested and the test conditions are the same as for the frequency characterization.
The definition of excitation was relatively complex. Exxelia wants the characterization to be close to the real conditions of Exxeliae for customers. The components are therefore supplied with a DC+AC current. In converters, the AC component is often triangular with a small but significant ripple, for example, 10% of the "full scale" DC. The measurement frequency was chosen to be 300kHz, a value that corresponds to the needs of the space market. Exxelia has defined a test set-up similar to a Buck converter in continuous mode. The choice we made was to keep the ripple and the frequency constant, whatever the DC current. The ripple was fixed at ±15% of the maximum DC current before the beginning of saturation for each component. The DC current was variable between 0 and a value leading to a 50% drop in inductance. The inductance was measured by the current rise slope. For each component tested, we checked whether the rising slope was a straight line, which shows that there is no saturation. If not, an average value was defined near the peak current value obtained. Saturation leads to two phenomena. Firstly, the appearance of harmonics which will deteriorate the EMC performance of the equipment. Secondly, as saturation increases, the drop in inductance becomes significant and the stored energy decreases. inductance measurement focuses on the first phenomenon with a short measurement time of the current rise, in order to well detect the beginning of saturation.
Care was also taken to ensure that the measurement times were sufficiently short and the measurements sufficiently spaced apart so that the temperature rises were negligible in order not to impact Best.
For each component of each size at room temperature, the no-load inductance value was first determined. Then the DC current value leading to a 50% drop in inductance was determined. It was decided to carry out fifteen measurements of L at injected DC currents not equally distributed between 0 and the maximum current determined previously, in order to correctly represent the saturation bend. For the curves at 125℃, the same reasoning was used, but with twelve measurement points in total, since saturation occurs earlier.
Figure 5 below shows an example of a curve obtained at room temperature.
Figure 6: Inductance versus current curve at room temperature for the CCM5 M33
The drop in inductance is well-defined. The curve does not have a rounded shape, but rather a break in slope. This is largely due to the choice to focus on the onset of saturation, which only appears at the end of the current rise, rather than a global saturation with a drop in stored energy, which would appear at a slightly higher current and would result in a smoother drop in inductance.
It can be seen that the maximum current before the start of saturation is a little higher than that written in the EXXELIA catalog and internet site. This phenomenon concerns all values and sizes. Documents will be updated shortly.
PART 3: OPTIMIZATION FOR MULTI-OUTPUT FLYBACK APPLICATIONS
The CCM family has been designed and qualified to produce both standard components, mainly inductors, and specific components, mainly transformers. In satellite equipment, the flyback converter has been widely used for a long time. It is simple and has a minimum number of components, which makes it reliable. The increase in the number of functions in the equipment has led to an increase in the number of outputs. This has led to an increasing problem often referred to as cross-regulation, but which is in fact a deviation of the voltages of some of the unregulated outputs from their theoretical value calculated during the design of the transformer and converter. EXXELIA was convinced that the transformer, especially through the choices made during the construction of the windings, is the main cause of this problem. Exxelia, therefore, decided to undertake a Ph.D. thesis on this subject with a scientific partner, the G2Elab laboratory in Grenoble.
Two phases have been defined in this work :
Phase 1 magnetic / transformer: Understand the magnetic problem inside the transformer, identify a theoretical model to represent the phenomenon, find an equivalent electrical circuit of the transformer compatible with classical circuit software, and finally find one or more design rules to minimize or avoid the problem.
Phase 2 power electronics/converter: Analyse the converter to identify which components play a role in the problem, understand the interactions between these components and the transformer, find a method of analysis to calculate voltage deviations, and choose a transformer/environment configuration that results in acceptable voltage deviations in the application.
In phase 1, Exxelia started with finite element simulation using FLUX software. Exxelia studied two transformers in CCM5 and CCM25 technology with 3 and 4 secondaries. Exxelia calculated the inductance matrix and then entered these values into the Psim software to calculate the output voltages. Exxelia made several observations :
The number of possible winding configurations is quickly enormous as the number of windings increases,
The problem is very sensitive to small variations of some coefficients of the inductance matrix,
The magnitude of the deviations depends on the (inhomogeneous) power distribution between the different windings,
The less powerful a winding is, the more sensitive it is to deviations.
Exxelia understood the link between the different types of windings and the voltage deviations. Then Exxelia looked for a mathematical model to represent the magnetic energy between the different windings wound in the copper window. Exxelia identified a method based on vector potential, making two simplifying assumptions: 1) only the magnetostatic behavior is taken into account, neglecting losses and parasitic capacitances, and 2) the leakage energy coming out of the magnetic circuit, for example in front of the air gap, is neglected, i.e. only the exchanges of energies between the windings in the copper window are taken into account. The calculation of the inductance matrix was compared in several cases with those from the simulation. The results were very satisfactory. This mathematical method has been published in [2].
Next, Exxelia looked for an equivalent electrical circuit that was sufficiently accurate to take into account voltage deviations and compatible with circuit simulation software. After several attempts, the extended Cantilever model was chosen. An example circuit is shown in Figure 6. Exxelia calculated the values of the elements of this model on several examples and then introduced this circuit into the Psim software to calculate the output voltages on these examples. The results were again satisfactory. We had all the right variations, often overvoltages, sometimes under voltages, and the deviation values were correct relative to the expected theoretical values. An example of voltage deviations obtained with a 4-output transformer is shown in figure 7. Exxelia also used this circuit by characterizing it from experimental measurements made on an existing "flight model" quality transformer. The results were satisfactory.
Figure 6: example of an equivalent extended Cantilever circuit for a 4-winding transformer
Figure 7: comparison of the voltage deviations obtained on 2 low power outputs for 3 different types of windings
Today, Exxelia has a good understanding of the impact of the choices made at the time of the construction of the windings on voltage deviations. Exxelia has understood that the leakage chokes between the secondaries have a major impact on the deviations. Exxelia was able to identify a link between winding order and geometry and voltage deviations. A simple design rule that we believe will avoid the worst cases of deviations has been developed. The whole approach has been published in [3].
Exxelia started phase 2 a few months ago. In this phase Exxelia is working in two directions: 1 the analysis of the influence of several components of the converter on the deviations, and 2 the search for an analytical method to calculate the output voltages in order to avoid having to use a circuit simulation software. We have already identified some faults in some components that have an influence on the deviations. We would like to go further, but we are faced with a delicate situation: depending on the application and the customer, the number and type of components used vary greatly. With regard to the method of calculating voltages, we are on a promising way.
In a summary, Exxelia has understood how the transformer influences voltage deviations and Exxelia is able to avoid the worst cases by choosing suitable winding processes. The final objective initially defined was to convince customers that the linear regulators they often add on low-power unregulated outputs are no longer necessary. This would lead to a reduction in cost, weight, and volume, and an increase in the reliability of the converters.
CONCLUSION
Initially, the CCM technology was created with two objectives in mind:
To complete a range of space components with higher and smaller footprint components at constant power
To have a technology family with casings in order to facilitate winding (time and cost reduction) and to improve the reproducibility of transformer characteristics, leakage inductances, and resistances in particular. Initialement, CCM technology was created with two goals:
To complete a range of space components with higher and smaller footprint components at constant power,
To have a technology family to facilitate winding (time and cost reduction) and to improve the reproducibility of transformer characteristics, leakage inductances, and resistances in particular.
The CNES/ESA ASF/TF qualification was a success and showed that even the heaviest CCM25 (45g), which can accept up to 200W, can withstand accelerations/shocks up to 2000g under certain conditions. The technology family allows for all kinds of standard or specific functions and products for all types of projects, full space, and new space.
Exxelia now has a complete set of information on the thermal behavior of all components, and in frequency and current saturation for standard inductors. All this information allows Exxelia to choose, together with the customer and for each application, the lightest/smallest product capable of transferring the required power level.
Finally, for multi-output Flyback converters, Exxelia has an analysis method that allows Exxelia to avoid the worst cases of voltage deviations (cross-regulation) by choosing suitable winding processes.
Exxelia is continuously proposing more through new technologies and design tools to offer their customers better solutions.
CCM TECHNOLOGY IS WELL ADAPTED FOR SPACE … AND Exxelia CONTINUE TO IMPROVE IT.
Autor : Bruno COGITORE – Jean PIERRE
Magnetic Expert / Innovation – Space product Manager • Exxelia Magnetics
REFERENCES
[1] G. Maigron, J. Pierre, « Agrément de Savoir-Faire : phase d’évaluation », EXXELIA, 2014
[2] D. Motte-Michelson, B. Cogitore, B. Ramdane, Y. Lembeye, “Application of a multi-winding magnetic component characterization method to optimize cross-regulation performances in DCM Flyback converters”, EPE ECCE 2022 proceedings, September 2022
[3] D. Motte-Michellon1,2, B. Cogitore1, Y. Lembeye2, B. Ramdane2, “A study on the influence of the transformer on cross-regulation in DCM multi-output flybacks”, 1 EXXELIA, France 2 Univ. Grenoble Alpes, CNRS, Grenoble INP, G2Elab, F-38000 Grenoble, France, PCIM 2022 proceedings, May 2022
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本文由清酒转载自Exxelia News,原文标题为:CCM, A FAMILY OF MAGNETIC COMPONENTS DEDICATED TO SPACE APPLICATIONS AND OPTIMIZED FOR MULTI-OUTPUT FLYBACK CONVERTERS,本站所有转载文章系出于传递更多信息之目的,且明确注明来源,不希望被转载的媒体或个人可与我们联系,我们将立即进行删除处理。
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目录- Company profile Wound Magnetics Component ENGINEERING SUPPORT High-Grade Technologies High Power Technologies Standard Technologies High-Grade Products Standard Products Built-to-Print Design Specification Form
型号- 3201008 AA 681 G,SBIT # 7.5S,MSCI 10 000 022 X Y 10,3201009 06 470 K,TCM22 1M5 H,ESI 01 M15 1X,TCM14 XXX H,3201009 03 560 K,3201008 AA 330 G,CMC 22 XXX 2WR SERIES,CMC22 1M6 2WR,MPCI H01 2K0 1XY,3201009 02 ### Y,DLEF 42,M83446/5-16*,CMC 22,ESI 7 8K4 1S,M83446/10-51**,MPCI 10 001 000 X Y 5,MSCI 12 470 000 X Y 10,MPCI 233 002 700,MSCI 12 560 000 X Y 10,* 20 082 000 X Y 10,3201008 05 3L4 L,HTSE47-5M6-10SR,MSCI 10 003 300 X Y 10,3201009 08 111 K,SESI 9.1 6K2 2WR,3201008 AA L022 K,M83446/5-15*,3201008 AA L022 J,DBIT X 7 P10A,CMC 14 ### XWR,SESI 32 4K9 1PR,SESI 22 10K 2WR,CMC 14,CMC 15,M83446/10-86**,CMC 17,3201008 AA 681 K,CMC 18,3201008 AA 681 J,SESI 18.1 W,3201009 01 470 K,3201009 02 6L4 M,SESI 32 84K 1PR,M83446/5-14*,DBIT 2 7S,CMC17 13M,SESI 9.1 M33 1WR,CCM25 M22 1W,EFD 20 SMD,WRFT42 13R 1X,3201009 07 ### Y,CMC 15 1M0 2WR,3201009 02 8L0 M,DBIT 1 7P10,MSCI 10 002 200 X Y 2,MSCI 10 002 200 X Y 5,MPCI 233 150 000,M83446/5-13*,SESI 9.1 10K 2WR,MPCI 12 680 000 X Y 5,MPCI H01 7K1 1TS 15,MPCI 10 006 800,CT91 075 231 WR,MSCI 12 068 000 X Y 5,HTSE,MPCI 233 560 000,M83446/10-64**,CCM 6 10K 1W,SESI 32WR,TT17,TT14,TT12,3201008 AA 121 G,SESI 9.1 26K 2WR,MSCI 10 000 033 X Y 5,TT19,SESI 15 33K 1SR,MPCI 12 027 000 X Y 5,MPCI 10 000 010 X Y 10,MPCI 12 027 000 X Y 2,* 20 000 010 X Y 10,HTSE47-10K-6SR,TT20,MSCI 12 270 000 X Y 10,M83446/10-95**,HTSE18-85K-1WR,SESI 14 M18 1SR,TT07,TT05,MPCI 12 018 000 X Y 5,MPCI 12 018 000 X Y 2,CMC18 M54 2WR,3201009 03 1L8 N,MSCI,MSCI H01 12K 1TS 15,TT09,TT08,MPCI 12 150 000 X Y 5,MSCI 10 000 220 X Y 10,MPCI 12 033 000 X Y 10,3201008 AA L18 K,3201008 AA 121 J,3201008 AA 121 K,M83446/5-19*,SESI 32 12K 1#R,3201009 03 120 M,MSCI 12 330 000 X Y 5,3201009 01 3L3 M,3201008 AA 561 G,HTSE91-65K-1WR,3201009 03 680 K,ESI 01 2K7 1X,M83446/5-18*,3201009 05 330 K,SESI 32 36K 1WR,TCM19 XXX V,3201009 05 681 K,M83446/10-73**,MPCI 233 000 270,DBIT 8 7P10,3201009 06 341 K,TT29,3201008 AA 2L7 K,CCM25 33K 1W,TT26,TT25,DBIT 5 7X400,PP-C4-9-1270,CMC 22 3M3 2WR,MPCI 10 000 470 X Y 5,SESI 9.1 M10 2WR,TCM22 47M H,MPCI 20 680 000,3201008 AA 330 K,3201008 AA 330 J,3201008 AA 561 J,3201008 AA 561 K,M83446/5-17*,HCESC10 56K 1X,SESI 32 M11 1WR,PPCDR-C20-35-565,3201008 AA 2L7 G,3201009 05 4L3 M,3201008 AA 2L7 J,MSCI 12 270 000 X Y 5,CCM 5 22K 1W,3201008 AA 4L7 G,MPCI 233 004 700,MPCI 10 001 500,MSCI 10 000 470 X Y 10,3201008 05 4L6 L,3201008 AA 4L7 J,SESI 9.1 M15 1WR,3201008 AA 4L7 K,HTSE XX WR,MSCI 12 120 000 X Y 10,SESI 32 53K 1#R,MSCI 10 004 700 X Y 2,MPCI 233 003 900,MSCI 10 004 700 X Y 5,SBIT 1 7.5S,SESI 15 M10 1WR,CMC14 M14 XWR,MSCI 10 000 068 X Y 5,MPCI 233 470 000,SBIT 8 7.5S,FW-C25-20-989,M83446/10-33**,SBIT 1 7.8P,* 20 056 000 X Y 10,SESI 15 6K4 1WR,3201009 02 1L5 N,SESI 22 33K 2WR,SESI 32 M83 1PR,3201009 08 360 M,CMC 18 60K 2WR,CMC22 M34 2WR,TCM19 3M3 V,CCM 20,SESI 18.1 WE,M83446/10-68**,ESI 7 K42 1S,MPCI 20 056 000,MSCI H01,CCM 25,TCM23 4M2 V,MPCI 233 220 000,3201009 08 120 N,CCM25 M10 1W,M83446/10-121**,3201009 02 820 K,MSCI 12 018 000 X Y 10,MSCI 10 000 082 X Y 10,CT 91 XXX 231 WR,EFD 15 SMD,M83446/10-99**,SESI 32 M83 1WR,MPCI H01 K38 1TS 15,SESI 32 M20 1WR,SESI 14 82K 1SR,ESI SERIES,SESI 32 4M7 1WR,GDT15 M50 60 1WR,SESI 32 36K 1PR,CMC22 M14 2WR,3201009 05 151 K,* 20 003 900 X Y 10,CMC18 1M1 2WR,M83446/10-42**,HCESC10 M47 1X,CMC18 2M4,MPCI 10000 SERIES,MPCI 233 12K H01 1X,MSCI 10 000 033 X Y 10,CCM 20 23K 1W,SESI 15 M10 1SR,3201009 08 351 K,HCESC10 56K,3201009 05 1L5 N,DBIT 2 3S,3201008 AA L27 K,MSCI H01 1K5 1TS 15,SESI 22 2M2 1WR,M83446/10-77**,3201009 01 150 M,MPCI 20 270 000,SESI 32 M11 1PR,MPCI H01 K67 1XY,HTSE15-M10-1WR/SR,3201009 03 151 K,3201008 AA 3L9 J,3201008 AA 3L9 K,* 20 022 000 X Y 10,3201008 AA 3L9 G,CCM 6 ### #W,SESI 15 56K 1SR,3201009 03 480 K,TCM23 10M V,CMESC17 1M2 1H,DBIT # 7 SA,MSCI 10 001 500 X Y 10,MPCI 12 047 000 X Y 10,M83446/10-20**,HTSE22-M71-1WR,M83446/10-59**,HTSE47-15K-6SR,3201008 AA 391 K,M83446/5-60*,CT91 050 231 WR,SESI SERIES,3201008 AA 391 J,3201008 AA 391 G,DBIT 8 7P*,3201008 AA L018 K,SESI 9.1WR,HTSE91-M31-1WR,CCM 20 3K3 1W,CCM25 2M2 1W,3201009 02 121 K,3201009 04 101 K,3201009 07 472 K,CCM 6 2M2 1W,SESI 18 WR,SESI 22 19K 2WR,TCM18 1M1 V,WRFT 4X SERIES,M83446/10-02**,HTSE22-17K-1WR,MSCI 10 001 800 X Y 5,M83446/10-37**,SESI 14SR,3201009 02 2L7 M,CCM 5 M10 1W,M83446/10-103**,3201009 03 160 M,3201010 01 402,WRFT42 5R0 1X,SESI 18 15K 1WR,M83446/10-90**,MPCI 20 015 000,3201009 02 232 K,MSCI H01 SERIES,MPCI 20 820 000,MPCI 12 012 000 X Y 10,3201008 AA 151 K,3201008 AA 271 K,3201008 05 1L0 L,CCM 6 68K 1W,3201009 02 330 M,3201008 AA 271 J,CCM 6 1M0 1W,MSCI 10 000 820 X Y 5,MPCI H01 M10 1TS 15,MPCI 10 000 820 X Y 5,3201008 AA 271 G,MSCI 10 000 560 X Y 5,MSCI 12 390 000 X Y 5,DBIT 8 7PA,SESI 15 ### #WR,SESI 32 73K 1#R,* 20 068 000 X Y 10,MSCI 10 000 039 X Y 10,3201009 08 730 K,* 20 000 039 X Y 10,MSCI 10 001 800 X Y 2,3201009 04 221 K,MPCI 12 1000 000 X Y 5,CMESC17 69M 1H,CMESC17 13M 1H,GDT91 6M0 135 1WR,* 20 001 000 X Y 10,3201008 AA L10 K,M83446/5-64*,TCM28 10M H,M83446/06-17,M83446/06
产品和解决方案
型号- 30 S4,SESI 9.1,731P,TEV,SCT,SESI 18,SESI 15,TEP SERIES,TEV SERIES,SESI 14,AS31,DLEF 42,C4N SERIES,CTS23,KM 111,CM12,C4E,CTS21,132P,CMC 22,ST79 SMD,253P,KM 915,FP-5-200,CT79 SMD,KM 78,KM 311-KM 21,OP SERIES,C4N,CEC,CA 158,CTC42,CTS41,744G,SC SERIES,SESI 22,CNC5X,PMR 64,CER,SPE0844S,CTC3E,NHB SERIES,CTS33,DBIT,CTS32,CMC 14,CA 152,CMC 15,KM 501-601,KM 82,MML-M SERIES,CMC 17,XBL SERIES,CMC 18,MML-C SERIES,KM 711-KM 7,CK SERIES,842P,SESI 32,FLYT,PMR 4,CT79E,MTLM 1234 MIL,PMA 64 T,C SERIES,TXR,CNC SERIES,CFS,TCK SERIES,KM 111 S,KM 111 T,MSCI 10000,CS SERIES,CE,710P,CF,SV,A 64 S4,CTC21,MIL-PRF-83421/06,HTSE 47 SR,MPCI 10000,CNC3X,ST79 HT200,CTS1M,R SERIES,HCESC,KCP 4 UA T,CTS4,CTS1,CTS13,MRA HT,734G,MKT,P.P.S 16 R,CFS SERIES,CNC5X SERIES,MKRS,MPA HT,SHD,CA 20,735P,PM 90,CA 30,PM 94,MP-4A,ESI 01,560P,SHR,KM 94S,CTC4,PM 980,CTC3,700P,HVD SERIES,XBL,PMA 64,PM 98,CM 04,PM 96,KPF-9,MPCI 12000,TKD,CA 40,WT83,CEC SERIES,FP- 60-700,682P,HVR SERIES,R 73 A,MPCI 233 H01,GDT 15,PM 720,DSCC 10004,810P,442P,430P,684P,SHR-SERIES,BIK SERIES,FL SERIE,CT79 HT200,KM 90,AP31,DMC 22 XXX 1WR,R 73 R,KM 97,PP 78 SERIES,C4E SERIES,KM 94,CT4E,CL SERIES,PM 730,TCF SERIES,BIK,431P,CA 15,SH SERIES,859P,CA 2,CA 1,MP4,PM 7,CT 91,HVA,AP41,HVD,SV SERIES,PM 90 S,CT 05 XXX 231 W,PM 948 S,MML-D SERIES,WS83,MML-D,MML-C,CTC4RSE,FLYT SERIES,HVR,LA SERIES,PM 948,CCM 6,CT79,MML-M,CCM 5,CCM 4,PM 50,TBC SERIES,A 74 S4 T,MPCI 20000,SPE0844,HTSE XX WR,BPM SERIES,PM 907 S,ST79,SHD-SERIES,KM 311-KM 21 T,PM 60,CNC,KM 50-60,880P,DCL-41,ESI 7,CT9E,KM 711-KM 7 T,882P,410P,CNR,CTC42E,CMR 07,TKD SERIES,MIL 39006/22,MKT S,CMR 04,CT 01 100 261 X,DSCC 93026,TCL SERIES,MIL 39006/25,CT 08 200 221 PR,PMR 4 T,TCH SERIES,C3N SERIES,CF SERIES,UBL,CN SERIES,PR 3 A,PM 96 T,PM 96 S,DCL-50,PRA HT,CTP42,UBZ,RA ...,KM 501-601T,DFC-11,FP-7-300,CEC5X,UBL SERIES,WRFT 4X,CCM 20,PP 3 M,HT SERIES,MSCI H01,CER SERIES,CCM 25,CMESC,PP 318,KPF,218P,860P,CEC5X SERIES,SMT47,CT79E HT200,PP 78,PM 907,PP 3 A,BI 73 R,PR 3 M,TBC,P.P.S 16 A,C3E SERIES,HVA SERIES,SBIT,KP-3C,CT 15 200 231 WR,KM 50-60T,DCL-14,TCN8X,P.P.S 13,HTSE XX SR,CTC21E,CTP21,TCN8X SERIES,PM 12,MPCI 233,TCF,TCE,TCH,TCL,DCL-23,TCK,TCN,BPM,CTS21E,TCM,PP 418,A 64 S4 T,FP-1-400,CNC3X SERIES,TCX,NHB,DCL-6,GDT 91,CMESC SERIES,MSCI 20000,TCM SERIES,CTS41RSE,CH SERIES,FP-11-500,PMR 64 T,30 S4 SERIES,CE SERIES,709G,CP SERIES,CT4,MPCI H01,TEF SERIES,PM 94 S,730P,CT9,730G,A 74 S4,FP-8C-1500,FP-4-150,CNR SERIES,C3E,TEF,UBZ SERIES,PS ...,CT 10,SCT SERIES,TEP,CT79E SMD,C3N,BI 73 A
Exxelia 商业航空用无源元件选型指南
描述- Exxelia brings its know-how to Aircraft, Helicopters and OEM manufacturers in numerous platforms for all types of critical functions including cockpit & avionics, engine & controls, actuation systems and power generation & distribution.
型号- PP,KM SERIES,TCF SERIES,DSCC 10004,BIK,CTC 21 SERIES,BIK SERIES,CCM,SESI,SH SERIES,CC SERIES,DSCC 93026,M39022,TCN SERIES,TCF,PM9X,CH SERIES,M83421,PM9X SERIES,CTC 21,TCN
Standex-Meder Unveils KSK-1A35/1 Reed Switch Providing an Operating Sensitivity Range of 20 to 35 Ampere-turns
At a maximum glass length of 10.5 and an overall lead length of 34.5mm, the KSK-1A35/1 can work with applications that may require the extra dimension of an ultra-miniature reed switch, while also providing an operating sensitivity range of 20 to 35 Ampere-turns (AT).
CCM 5 1W高可靠性应用SMD功率电感器
描述- 该资料介绍了Wound Magnetics Technologies公司的SMD功率电感器CCM 5系列产品,适用于高可靠性应用。产品具有符合ECSS-Q-70-02、MIL-STD-202和DO-160标准的特点,满足ESCC 3201/011规范,材料达到UL94-V0等级,适合红外和蒸汽回流焊接,频率范围高达1 MHz,工作温度范围为-55°C至+125°C。
型号- CCM 5 22K 1W,CCM 5 M15 1W,CCM 5 1M0 1W,CCM 5 2K2 1W,CCM 5 6K8 1W,CCM 5 ####W,CCM 5 M10 1W,CCM 5 48K 1W,CCM 5 3K4 1W,CCM 5 M48 1W,CCM 5 M67 1W,CCM 5,CCM 5 10K 1W,CCM 5 1K5 1W,CCM 5 32K 1W,CCM 5 M22 1W,CCM5,CCM 5 M33 1W,CCM 5 68K 1W,CCM 5 4K6 1W,CCM 5 14K 1W,CCM 5 1M5 1W
CCM 6 1W高可靠性应用SMD功率电感器
描述- 该资料介绍了Wound Magnetics Technologies公司生产的SMD功率电感器,适用于高可靠性应用。这些电感器符合ECSS-Q-70-02、MIL-STD-202和DO-160标准,并满足ESCC 3201/011规范。它们采用UL94-V0等级材料,适合红外和蒸汽回流焊接,频率范围高达1 MHz,工作温度范围为-55°C至+125°C。
型号- CCM 6 3K4 1W,CCM 6 22K 1W,CCM 6 2K2 1W,CCM 6 6K7 1W,CCM 6 33K 1W,CCM 6 M10 1W,CCM 6 M33 1W,CCM 6 M15 1W,CCM 6 2M2 1W,CCM 6 M68 1W,CCM 6 ####W,CCM 6 47K 1W,CCM 6 15K 1W,CCM 6 M47 1W,CCM 6 M22 1W,CCM 6 4K7 1W,CCM 6 68K 1W,CCM 6 1M0 1W,CCM 6 1M5 1W,CCM 6 10K 1W
SMD功率电感器CCM 5 1W高可靠性应用
描述- 该资料介绍了Wound Magnetics Technologies公司生产的SMD功率电感器,适用于高可靠性应用。产品符合ECSS-Q-70-02、MIL-STD-202和DO-160标准,并满足ESCC 3201/011规范。材料达到UL94-V0等级,适合红外和蒸汽回流焊接。频率范围高达1 MHz,工作温度范围为-55°C至+125°C。
型号- CCM 5 22K 1W,CCM 5 1M0 1W,CCM 5 2K2 1W,CCM 5 M10 1W,CCM 5 48K 1W,CCM 6,CCM 5,CCM 4,CCM 5 1K5 1W,CCM 5 M33 1W,CCM 5 68K 1W,CCM 5 M15 1W,CCM20,CCM 5 6K8 1W,CCM 5 3K4 1W,CCM 5 M48 1W,CCM 5 M67 1W,CCM 5 10K 1W,CCM 5 32K 1W,CCM6,CCM 5 M22 1W,CCM5,CCM4,CCM 20,CCM 5 4K6 1W,CCM 5 14K 1W,CCM 5 1M5 1W,CCM 25,CCM25
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