Sådan laver du et simpelt printkort

Hvis du vil lave dit eget printkort, er her nogle trin, du kan følge. De omfatter de materialer, du skal bruge, beregning af impedanser og lodning. Når du har styr på disse trin, kan du gå videre med projektet og lave et mere komplekst printkort.

Trin til fremstilling af et printkort

Der er nogle få trin i fremstillingen af et printkort. Det første trin er at forberede dit skema. Det giver dig mulighed for at planlægge placeringen af komponenterne. Når du har skemaet, skal du importere det til dit CAD-system. Dernæst skal du placere komponenternes fodaftryk inden for printkortets omrids. Disse footprints viser netforbindelserne som ghost-line-billeder, der indikerer, hvilke dele der er forbundet med hinanden. Dernæst placerer du komponenterne på printkortet under hensyntagen til den bedste placering for den bedste ydeevne, såsom minimering af elektrisk støj og overdreven varme. Du skal også tage højde for eventuelle fysiske forhindringer, såsom kabler, stik eller monteringshardware.

Når lagene er klar, fjernes et kobbersubstrat. Kobberlaget vil fungere som printkortets base. De ydre lag vil blive fastgjort til det med stifter. Når lagene er blevet placeret, er printkortet klar til limning. Det yderste lag vil være et glasfibermateriale, der er præimprægneret med epoxyharpiks. Dette materiale vil også dække det oprindelige substrat og eventuelle ætsninger af kobberspor. Det sidste trin er at samle pladen ved hjælp af et tungt stålbord. Under samleprocessen sættes lagene sammen med stifter, hvilket sikrer, at de ikke forskubber sig under justeringen.

Nødvendige materialer

For at lave et printkort skal du først købe et printkort (PCB). Et printkort består af tre lag: et ledende lag (som regel kobber), der er omsluttet af to lag ikke-ledende materiale. Endelig er der ledningerne, som forbinder de forskellige dele af kredsløbet. Disse ledninger kan komme i forskellige farver og længder, og nogle har klemmer eller clips i den ene ende.

PCB'er er lavet af mange forskellige materialer, og derfor er det vigtigt at vælge det rigtige materiale til dit kredsløb. Forskellige materialer har forskellige egenskaber og kan forbedre dit kredsløbs ydeevne. For eksempel er nogle materialer bedre egnet til højhastighedsapplikationer end andre, mens andre er bedre til højtemperaturapplikationer.

Lodning

Hvis du overvejer at lave dine egne elektroniske kredsløb, er der mange måder, du kan komme i gang på, herunder lodning af et simpelt printkort. At bruge de rigtige værktøjer er en vigtig del af denne proces, da korrekt udstyr og teknikker vil gøre det muligt for dig at fuldføre opgaven med succes. Du kan f.eks. bruge en wire cutter til at klippe ledningerne over. Dette værktøj skal være skarpt og have en affaset kant, så det giver et rent og fladt snit. Det er med til at minimere risikoen for kortslutning. Når du klipper ledningerne over, skal du huske at holde fast i den overskydende ledning, så den ikke flyder ud over det hele.

Før du lodder, skal du rengøre området omkring hver komponent med en våd svamp. Du kan også bruge en almindelig svamp til at rengøre spidsen af din loddekolbe. Du skal også sikre dig, at du har den rigtige loddekolbe, som skal have en temperatur på 400 grader Celsius. Sørg også for at mærke alle komponenter ordentligt og lægge dem ordentligt ud. Du bør også bruge en jordet håndledsrem for at reducere mængden af statisk elektricitet.

Samling

Montering af et simpelt printkort indebærer, at man sætter mange komponenter sammen på et stykke printkort. Disse komponenter er generelt lavet af metal og er monteret på printpladen gennem metalflige. De kan monteres manuelt på printpladen og loddes til puderne på den anden side af printpladen, eller de kan monteres på printpladen ved hjælp af en automatiseret indsætningsmonteringsmaskine. Uanset om de monteres manuelt eller ej, giver overflademontering mulighed for en høj tæthed af kredsløbet og minimerer størrelsen af det færdige produkt.

Kredsløbssæt indeholder normalt 5 komplette kredsløbskort, men du kan ofte bestille flere. De fleste vil ikke fortryde, at de bestiller mere, end de har brug for, da de ofte ender med at bruge ekstra komponenter under test eller debugging. De ubrugte dele er ofte mærket DNP eller "Do Not Populate" for at indikere, at de ikke er en del af produktionsdesignet.

Sådan læser du et printkort

There are some basic things that you should know when trying to understand how to read a PCB. For instance, you need to understand what a resistor is. A resistor is a piece of metal that has a measurable resistance. Usually, a resistor is marked with an ohm measurement mark. The ohm symbol looks like the Greek letter Omega. The value 100MO means one hundred megaohms. You should also know how to identify a capacitor. Lastly, a board may be marked with traces or components.

Analyzing a board along the signal flow

The design of a PCB can be complicated. Many of the components are layered with a different signal flow. This can cause signal integrity issues when high-speed transmission lines must pass through dense via areas or split planes. Analyzing a board along the signal flow can help you determine which components should be placed where to minimize signal integrity problems.

The distribution properties of a PCB will greatly affect the signal, particularly at high frequencies. For example, high-frequency communication systems will often suffer from ground return, which occurs when the signal current changes rapidly with the external magnetic field. This causes reverse current flow in the surrounding conductors. This effect is illustrated by a ground plane diagram.

Identifying components

The first step in identifying components on a PCB is to identify the board. There are many PCBs marked with codes and acronyms to help you determine the application. For example, a DMCB board is the DOS Main Control Board for a GE Mark V computer. Another example is a daughterboard, which attaches to the motherboard and allows access to the CPU and memory.

Each component has a marking on its body and packaging. This marking will show its value, polarity, and tolerance. In addition, there may be a color-coded band that indicates the resistance. The bill of materials will also list the component parts and their quantities. There are also reference designators that show where the components are located.

Identifying traces

When reading a PCB, you need to identify traces. These are not wires, but are the pathways through which electrical current flows. Each path has a specific resistance, and it is important to consider this when selecting trace widths. The resistance of a path can be determined by its temperature rise, which shows how hot the trace will become when current flows through it. The temperature rise is usually the difference between the operating temperature and the maximum operating temperature.

The signal pulse on a trace travels at a rate of 84-85 picoseconds per inch in air. The signal travels at about 11.8 inches per nanosecond in vacuum, and about 145 picoseconds per inch for a common dielectric material. The propagation delay of an electrical signal depends on the design specifications, but there is a general guideline that you can follow for most PCBs.

Cleaning a board

Cleaning a PCB is a delicate process that requires a certain amount of care. Most PCB contamination is caused by the flux residues that accumulate after assembly. To get rid of this, you can use a solvent or an abrasive to clean the board thoroughly. Paper towels and kimwipes are good options to soak up the solvent or abrasive. After cleaning, make sure to wipe the board clean to remove any remaining lint.

Different types of solvents are used for PCB cleaning. Some of these solvents are mild, while others are flammable. Cleaning a PCB with a solvent can improve its performance. You can use foam or cotton swabs that are saturated with a mild solvent. Many pump dispensers sell this type of cleaning solvent. Presaturated wipes that contain isopropyl alcohol can also be used.

Repairing a board

One way to repair a PCB is to remove the damaged components and the adhesive that sticks them to the board. This can be difficult if the adhesive is dry or old. You can use workbench cleaners, which are usually consumer products.

Once you have removed the damaged components, you can use an oscilloscope to check the continuity of the circuit across the board. If you find a burned area, it means the component has failed and has to be replaced. If you don’t know where the failed component is located, you can use tweezers to lift it and replace it.

Når printkort bruges i fremstillingen af en enhed

Når printkort bruges i fremstillingen af en enhed, kaldes de trykte printkort. Der findes mange forskellige typer printkort. De omfatter kobberbelagte printkort, overflademonteret teknologi og galvaniserede huller. Hvis du forstår forskellene mellem de forskellige typer printkort, kan du træffe en informeret beslutning om, hvilken type du har brug for til netop din enhed.

Indpakning af tråd

Wire wrapping er en af de hurtigste måder at installere et printkort på. Det kræver dog et vist niveau af ekspertise. Når det gøres korrekt, vil en wire wrapped forbindelse have en kontaktmodstand, der svarer til en loddet forbindelse. Det er også relativt nemt at ændre. Når du bruger et wire wrap-værktøj, er det vigtigt, at du kun bruger tre wraps pr. pol. Du bør også undgå at lave margueritkæder, når du vikler ledninger.

Wire wrapping er en proces, hvor to elektriske kontakter forbindes ved at vikle en kobbertråd omkring dem. Det er en meget pålidelig forbindelsesmetode og er ofte det første skridt for begyndere inden for elektronik. Du kan enten bruge et manuelt værktøj eller en wire wrapping-maskine.

Kobberbeklædt plade

Kobberbeklædte plader bruges ofte til fremstilling af elektroniske enheder, da de kan give mekanisk støtte og elektriske forbindelser mellem komponenter i et kredsløb. Kobber er en god leder af elektricitet, så det er et ideelt materiale til beklædning af PCB'er. Brugen af kobber i elektronisk udstyr er stigende, og mange PCB'er har nu kobberbeklædte PCB'er.

Den proces, der bruges til at fremstille kobberbeklædt laminat, omfatter udglødning af laminatet. Denne procedure reducerer den termiske udvidelseskoefficient og reducerer den dielektriske konstant.

Overflademonteret teknologi

Overflademonteringsteknologi er en ny måde at fremstille printkort på. Teknologien er mere effektiv og kræver færre trin for at fremstille et printkort. Det giver designerne mulighed for at få plads til flere elementer på et mindre printkort. Det gør processen mere omkostningseffektiv. Derudover er overflademonterede komponenter bredt tilgængelige og relativt billige. De kan også fremstilles på meget kortere tid end andre teknologier.

Overflademonteringsteknologi bruges i vid udstrækning til fremstilling af printkort. Processen begynder med en designfase, hvor man udvælger komponenterne og designer SMT'en. Der findes forskellige softwareværktøjer, som kan hjælpe med designprocessen. Derefter sendes printkortets data til en produktionsvirksomhed. Data for overfladefinishen sendes også.

Elektropletterede huller

Plating er en proces, der gør huller i printkort ledende. Kobber deponeres i hullerne ved hjælp af elektroplettering. Processen er nøje kontrolleret og indebærer, at printpladerne skiftevis dyppes i rengøringsopløsninger og pletteringsopløsninger. Derefter fjernes det overskydende kobber. Processen er også kendt som through-plating.

Elektropletterede huller i printkort er vigtige for layoutets overordnede succes. Forkert placering kan forårsage fremstillingsproblemer og forringe det endelige produkts ydeevne. For at undgå disse problemer er det vigtigt at bruge hullerne korrekt.

Tangent til tab

For at kunne bestemme tabstangenten bør signalintegritetsingeniører kende det materiale, der bruges til at fremstille printpladerne. De materialer, der bruges, er ofte en kombination af glas og resin. Forskellige typer af disse materialer vil have forskellige tabstangenter. I nogle tilfælde kan en producent ikke levere tabstangentværdier for de materialer, de bruger, så signalintegritetsingeniører skal selv bestemme disse.

Et materiales tabstangent er et mål for den mængde elektromagnetisk energi, det absorberer ved en bestemt frekvens. Materialer med en lav tabstangent vil reducere transmissionstabet. Andre faktorer, der kan påvirke ydeevnen, omfatter overfladens ruhed og lagets aflejringsopløsning. Derudover er varmeledningsevne en anden vigtig faktor, da den bestemmer, hvor godt et materiale leder varme. Dårlig varmeledningsevne begrænser enhedens ydeevne og kan begrænse ydeevnen for en stak.

Dielektrisk konstant

Når man fremstiller printkort, er det vigtigt at kende den dielektriske konstant for de anvendte materialer. Det er en vigtig parameter, fordi den hjælper dig med at vælge det rigtige laminat. De fleste laminatleverandører kan give denne information samt frekvens og resinindhold. Du kan også beregne den dielektriske konstant for et printkort ved hjælp af et program som Altium Designer. Alternativt kan du bruge et simuleringsværktøj som Simberian.

PCB-materialer er normalt fremstillet af glasfiber, kobber eller plast. Forskellige typer af disse materialer har forskellige dielektriske konstanter, som vil påvirke deres elektriske egenskaber. Den dielektriske konstant (også kaldet dissipationsfaktoren) angiver mængden af ladning, der kan eksistere mellem to ledere, når der tilføres en spænding mellem dem. Denne egenskab bestemmer den hastighed, hvormed strømmen flyder i lederen.

Miljøtest til printkort

Fremstillingen af elektroniske enheder som f.eks. printkort skal gennemgå en række miljømæssige tests, herunder fugtigheds- og termiske chok-tests. Disse tests vil afgøre, om et printkort kan modstå virkningerne af fugtighed og korrosion. Et printkort kan også gennemgå en funktionstest. Denne type test simulerer de faktiske driftsforhold og giver øjeblikkelig feedback på kvaliteten af et projekt. Den bruges i stigende grad til produktion af små partier for at sikre, at hvert printkort opfylder alle kvalitetskrav til brug i marken.

Miljøtest af printkort, der bruges til fremstilling af elektronik, er afgørende for at sikre deres pålidelighed. Selvom det ikke altid er lovpligtigt, er disse tests afgørende for elektroniske produkters pålidelighed og sikrer, at de fungerer efter hensigten. Det er vigtigt at vælge en erfaren kontraktproducent af elektronik med de nødvendige interne faciliteter til at udføre disse tests.

How to Trace Circuit Boards

PCB trace width

One of the most important design elements of a PCB is the trace width. Trace width is the distance between two adjacent components on a circuit board. A proper trace width prevents transient short circuits and signal interference. A general rule is to leave three times the trace width between parallel running traces. Other important considerations when choosing trace width include where the power, ground, and signal traces should run. It is best not to run power traces from one component to another in a daisy chain configuration. Furthermore, the proper trace width should be calculated based on the expected current requirements of the circuit board.

Trace width can be determined using a PCB trace width calculator. This calculator uses various values such as the thickness of copper, cross-sectional area, and conductive material to estimate PCB trace width. A wide trace can contribute to uneven heating, which results in poor solder joints. In addition, small two-pin parts that are connected to a large portion of metal on a pad might end up being pulled up on one end during solder reflow. This problem is known as tombstoning, and requires manual rework to correct.

PCB trace thickness

The PCB trace thickness is an important design consideration. The wrong thickness could lead to sparks and damage to connected components. Fortunately, PCB trace thickness calculators exist to help designers determine the best trace thickness for a specific design. These calculators can also help determine the width of a PCB trace.

The most common PCB trace thickness is 1 oz, though it can be made a bit thicker with a special specification. Copper traces tend to heat up as current flows through them, so it’s important to use the appropriate thickness for your PCB design. In addition to determining the thickness of a PCB trace, it’s important to keep the overall circuit loop thermally stable.

In addition to trace width, you should also consider the voltage and current flow through your PCB. These two factors are important because they determine how well the board can handle the current flow. The IPC-2221 standard contains values for trace thickness, internal and external layers, and trace temperature. These values are measured in amps and volts. Using the proper trace width can greatly improve the performance of your electronic gadget.

PCB trace current

Tracing circuit board current is a crucial task in design. It is important to calculate the current carrying capacity of a PCB, which can be done with the aid of formulas. A PCB’s current carrying capacity depends on several factors, including the operating temperature and amount of current that must pass through each trace. In addition, the width of the trace is also a factor to consider.

PCBs with high current ratings must be thermally isolated, so it is advisable to use thermal-relief connections and board cutouts to prevent the components from overheating. Also, if the trace is too narrow or has too little copper, you can apply additional solder. This will increase the trace’s thickness and reduce its resistance, thereby allowing more current to pass through.

PCB trace coupling

PCB trace coupling refers to the crosstalk that occurs between two signals that travel through the same layer on the board. The distance between two traces on the same layer determines how much coupling is present. The longer the distance between traces, the less coupling is present. The length of a single trace is proportional to the frequency of the signal.

When the current flowing through a single PCB trace crosses an adjacent trace, it creates an electric field and induces an electromotive force. This phenomenon is governed by Faraday’s second law of induction and can compromise the integrity of a signal on the same trace.

Using a DMM to measure trace resistance

Trace resistance is the resistance of circuit board traces. It’s an important parameter, as too high or too low trace resistance can affect the functionality of a circuit. It can also lead to design or implementation problems. Therefore, it’s important to understand trace resistance in order to ensure that your circuits are running smoothly.

The simplest method to measure trace resistance is with a digital multimeter. The DMM understands Ohm’s law and can calculate resistance simply by measuring the voltage drop. However, this approach will only work if the resistor is isolated. You’ll need to connect the multimeter probes to the resistor and then power up the circuit.

Using a DMM to measure trace resistivity on circuit board helps you determine if a particular component is failing. You can determine if the component is defective if the trace resistance on a circuit board is too high. The resistivity of a component will increase as the temperature increases.

How Much is a Circuit Board?

If you’re in the market for a printed circuit board, you may be wondering how much it will cost to produce it. This article will examine the materials, assembly, and testing costs of a PCB. You’ll be able to compare costs from different sources and make an informed decision for your project.

Cost of a printed circuit board

The cost of a printed circuit board is based on a variety of factors, such as the component used and the manufacturing process. The more complicated the component, the higher the cost of the circuit board. To reduce costs, use standard components and standard processing requirements. A good way to identify unnecessary costs is to analyze the bill of materials.

The size and type of the printed circuit board can also affect the cost. Smaller, 2 layer PCBs may be more expensive than larger, 3×6 circuit boards. Mixed copper weights are also more expensive and require more time to manufacture. Additionally, thicker and more expensive materials have longer lead times, so take those into account before making your final decision.

The thickness of a PCB also plays a role in its cost. A three-layer PCB is significantly more expensive to produce than a single-layer PCB. The number of layers, the material used, and the size of the board all influence price. More layers mean more work, so the price of the final product increases.

Cost of PCB materials

The cost of PCB materials is one of the key factors that drive production costs. A variety of factors influence the price of materials, including size, weight, and the type of board. For instance, the price of copper foil makes up more than 50% of the total cost of thicker and thinner PCBs.

The best PCB materials should be durable enough to withstand physical stress and keep the components connected. High-frequency PCB boards require special materials, such as FR4. Moreover, the thermal properties of a PCB board should be considered. If the temperature is cold, higher-grade materials will be required.

The cost of PCB assembly also varies depending on the complexity of the design, labor rate, and other factors. However, the cost of PCB assembly is generally less expensive if it is performed at a low-cost facility. Labor rates vary according to the size of the PCBs and the number of components that need to be connected.

Cost of PCB assembly

One of the biggest factors in the cost of PCB assembly is the turnaround time. This is the amount of time it takes to complete the manufacturing process, and the shorter the turnaround time, the higher the cost. Buyers should be aware that faster turnaround times often drive up the cost of PCB assembly by as much as one third. They should also be aware that expedited shipping costs more than regular shipping.

The cost of PCB assembly increases if the production of the PCB is complicated and requires several layers. The availability of panels affects the cost, so it is vital to shop around. A basic, double-sided board costs about $16. However, some PCB manufacturers charge extra for extra layers.

A PCB’s cost also rises if the PCB needs to be customized. This can include trace size and coating. Customized PCBs may also require special assembly.

Cost of PCB testing

Cost of PCB testing varies greatly depending on the complexity of the board and the method of testing used. Some methods, such as in-circuit testing (ICT), are more expensive than others. In-circuit testing focuses on checking each individual element and electronic characteristic of the board. It requires a custom bed of nails and is ideal for high volume productions.

Dedicated fixtures and tools are expensive. They require storage space, are difficult to disassemble and require additional labor. They also need to be reordered. As a result, the cost of testing PCBs can be quite high. However, most PCB manufacturers now have their own flying test probe machines, which has significantly lowered testing costs. Additionally, some manufacturers waive ET charges for orders larger than a certain value.

Functional testing is another option for testing PCBs. This type of testing can identify defects, open connections, and solder shorts in the circuits. It helps ensure that the assembly process is as accurate as possible. However, it does require additional costs, ranging from $0.1 to $1 per PCB assembly.