Cleaning of Printed Circuit Assemblies with Surface-Mounted Components

Arzigian, J. S.

11 1900

International Telemetering Conference Proceedings / October 30-November 02, 1989 / Town & Country Hotel & Convention Center, San Diego, California / The need for ever-increasing miniaturization of airborne instrumentation through the use of surface mounted components closely placed on printed circuit boards highlights problems with traditional board cleaning methods. The reliability of assemblies which have been cleaned with vapor degreasing and spray cleaning can be seriously compromised by residual contaminants leading to solder joint failure, board corrosion, and even electrical failure of the mounted parts. In addition, recent government actions to eliminate fully halogenated chlorofluorocarbons (CFC) and chlorinated hydrocarbons from the industrial environment require the development of new cleaning materials and techniques. This paper will discuss alternative cleaning materials and techniques and results that can be expected with them. Particular emphasis will be placed on problems related to surface-mounted parts. These new techniques may lead to improved circuit reliability and, at the same time, be less expensive and less environmentally hazardous than the traditional systems.

Printed circuit cleaning

solvent cleaning

Verifiering av speciell tvättutrustning med avseende på renhetsgrad / Verification of special washing equipment with regard to level of cleanliness

Langmo, Jotham

January 2021

Inom medicin och kärnkraft ställs höga krav på olika komponenters renhetsgrad. Vid tillverkning av precisionskomponenter inom medicin och kärnkraftsteknik så används skärvätska för att kyla och smörja godset. Skärvätskan behöver tvättas bort innan komponenterna skickas till kunderna. För att kunna tvätta bort skärvätskan används en speciell tvättutrustning. Idag saknas en metod för att kunna påvisa att den speciella tvättutrustningen på ett tillförlitligt sätt uppnår gällande krav och standarder på renhet som ställs av branscherna, på komponenterna. Genom att verifiera tvättutrustningen mot en specifik kravbild, godkänns tvättutrustningens duglighet och således frisläpps utrustningen för produktion. Målet med studien är att ta fram ett underlag för att kunna verifiera en speciell tvättutrustning. Målet uppnås genom att undersöka vilka faktorer som påverkar renhetsgraden i tvättprocessen och utveckla metoder för att säkerställa att dessa faktorer beaktas. Några av metoderna som används i arbetet är Plan-Do-Study-Act (PDSA), Acceptanskontroll enligt attributsmetoden, intervju och observation. Resultatet av provgruppsmätningarna från laboratoriet, visar att komponenternas renhetsgrad ligger inom Willos kravställning på restkontamination av olja≤10 μg/cm^2 då komponenterna tvättats med tvättprogram två. Efter att provgupperna genomgått acceptanskontrollen står det klart att provgrupperna accepteras med en sannolikhet på 95,6% och att tvättprocessen är stabil. I studien har gamla och antagna mätvärdena använts eftersom det tar lång tid att ta laboratorieprover och tiden som examensarbetet pågår är begränsad. Med de gamla och antagna mätvärdena skulle den speciella tvättutrustningen kunna verifieras mot Willos kravställning, för att möta branschernas krav på renhetsgrad. Genom verifieringen kan man på så vis påvisa att tvättutrustningen levererar stabilt tvättresultat över tid. / In medical and nuclear power applications, high demands are placed on the level of cleanliness of various components. When precision components in medicine and nuclear power technology are manufactured, cutting fluid is used to cool and lubricate the raw stock. The cutting fluid needs to be washed away before the components are sent to customers. To be able to wash away the cutting fluid, special washing equipment is used. Today, there is no method to demonstrate that the special washing equipment reliably meets current requirements and standards for cleanliness set by the industries on the components. By verifying the washing equipment against specific requirements, the capability of the washing equipment is approved, and thus, the equipment is released for production. The study aims to produce a basis for verifying special washing equipment. The goal is achieved by examining which factors affect the level of cleanliness in the washing process and developing methods to ensure that these factors are taken into account. Some of the methods used in work are Plan-Do-Study-Act (PDSA), Acceptance sampling according to the attribute method, interview and observation. The results of the test group measurements from the laboratory show that the level of cleanliness on the components is within Willo's requirements for residual contamination of oil≤10 μg/cm^2 when the components have been washed with washing program two. After the sample groups have undergone the acceptance sampling, it is clear that the sample groups are accepted with a probability of 95.6% and that the washing process is stable. In the study, old and assumed measurement values have been used because of the time it takes to perform laboratory samples, and the time that the degree project progresses is limited. With the old and assumed measurement values, the special washing equipment could be verified to Willo's requirements in order to meet the industries' requirements for the level of cleanliness. Through the verification, it can be demonstrated that the washing equipment delivers stable washing results over time.

Special Washing Equipment

Washing Equipment

Washing

Hydrocarbon

Hydrocarbon Solvent Cleaning

Dürr

Eco Clean

Dürr Eco Compact 80c

Verification

Validation

Cleanliness

Surface Cleanliness

Surface

Clean

Solvent

Ultrasonic Washing

Ultrasonic

Vacuum Clean

Vacuum.

Speciell Tvättutrustning

Tvättutrustning

Tvättning

Hydrocarbon

Hydrocarbon Solvent Cleaning

Dürr

Eco Clean

Dürr Eco Compact 80c

Verifiering

Validiering

Verification

Washing Equipment

Renhetsgrad

Ytrenhet

Surface

Clean

Lösningsmedel

Ultraljudstvätt

Ultraljud

Vakuum Renjörning

Vakuum.

Mechanical Engineering

Maskinteknik