Impregnation of electrcal machines with solventless resins

Sharma, Chandan; Vadera, K.; Agarwal, Rohit

doi:10.1108/eb043006

Cited by 3 publications

(3 citation statements)

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“…The exponential relation (see Equation ( 17)) perfectly fits the data set with the fitting parameter as y o = 14.50 ± 0.70, A = 9.64 ± 1.90, and R o = −5.31 × 10 −4 , with the statistical relation error α = 0.1 (as exhibited in Table 1). Equation (17) almost confirms the exponential decrease in percent bubbled coils up to 55 ± 5 min. Intercept y o represents the minimum bubble proportion in the manufactured coils with preheating above 60 • C, i.e., 13.07 ± 1.70%.…”

Section: Pre and Process Heating Of Coilssupporting

confidence: 62%

“…Hence, an existing potting method was modified by changing several parameters during the insulation process to minimise the percentage of bubbles in the ignition coils. However, its non-economical maintenance entailed procedures and processes, i.e., vacuum impregnation (VI) and vacuum pressure impregnation (VPI), which were used to mitigate bubbles-related problems [17]. However, bubbles are formed in coils manufactured from these two processes due to the development of partial pressure in the vacuum chamber.…”

Section: Introductionmentioning

confidence: 99%

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One Factor at a Time Analysis to Modify Potting Technique for Manufacturing of Bubble-Free High-Voltage Polyester Insulated Automotive Coils

Nawaz

Ahmad

Akram

et al. 2022

Designs

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The current study focuses on minimising the bubbles in polyester-insulated ignition coils, which were produced with a defect level of ~21–25% or 210–250 coils per 1000 batch size by using the potting method. This high-level rejection makes a substantial financial impact by increasing waste material, manufacturing, and after-sales costs. Hence, to control the bubbled problem without using expensive and maintenance-heavy techniques, the process parameters in the potting method were alternated and investigated using one factor at a time, which played a vital role in the formation/reduction of bubbles in the ignition coil insulation. Process parameters, including pre/process heating, the appropriate MEKP/cobalt naphthenate ratio, the pouring amount/increments, and the stirring speeds, reduced the bubble formation per lot from 205 ± 30 to 146 ± 25, 108 ± 21, 61 ± 17, and 10 ± 2 per 1000 lot accordingly. In addition, a comparative study was conducted in terms of performance and life cycle endurance, using Japanese and Indian standards. Furthermore, an after-sale warranty claim also supports the proposed changes in the potting technique. This modification may reduce the after-sales rejection within two years to approximately ~85%. This modification in the potting technique is extremely cost-effective in comparison to expensive processes, i.e., vacuum-pressure impregnation and vacuum impregnation, which require extensive labour and maintenance.

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Section: Pre and Process Heating Of Coilssupporting

confidence: 62%

Section: Introductionmentioning

confidence: 99%

One Factor at a Time Analysis to Modify Potting Technique for Manufacturing of Bubble-Free High-Voltage Polyester Insulated Automotive Coils

Nawaz

Ahmad

Akram

et al. 2022

Designs

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“…Impregnation with this process is done with highly viscous resin [11,13]. It needs high investment and is time-consuming process.…”

Section: Vacuum Pressure Impregnationmentioning

confidence: 99%

Polyester Usage in Manufacturing of Electrical and Mechanical Products and Assemblies

Nawaz¹,

Islam²,

Khattak³

et al. 2018

Polyester - Production, Characterization and Innovative Applications

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This chapter focuses on the processes in which polyester is usually used for the manufacturing of mechanical components and assemblies. Various methods of manufacturing these products are mentioned in this chapter. These methods include wet layup method, filament winding, pultrusion, vacuum bagging and autoclave curing, resin transfer molding (RTM) and vacuum-assisted resin transfer molding (VARTM). Various production levels and properties can be achieved by polyester resin using abovementioned processes. Each process has its own benefits and disadvantages, which are discussed in this chapter. Furthermore, the use of polyester in making electrical insulation is also discussed in the chapter. Advantages and disadvantages of each impregnation technique are also explained.

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Failure of Polyester Laminated Automotive Ignition Coils Influenced by Environmental Factors

et al. 2015

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Impregnation of electrcal machines with solventless resins

Cited by 3 publications

References 0 publications

One Factor at a Time Analysis to Modify Potting Technique for Manufacturing of Bubble-Free High-Voltage Polyester Insulated Automotive Coils

One Factor at a Time Analysis to Modify Potting Technique for Manufacturing of Bubble-Free High-Voltage Polyester Insulated Automotive Coils

Polyester Usage in Manufacturing of Electrical and Mechanical Products and Assemblies

Failure of Polyester Laminated Automotive Ignition Coils Influenced by Environmental Factors

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