Ehdotuksia PCB-asettelun suunnitteluun juotoskulmasta käsin

Ehdotuksia PCB-asettelun suunnitteluun juotoskulmasta käsin

When designing a circuit board, there are several things to keep in mind, including the soldering angle. In general, you should avoid soldering with your face directly above the joint. To avoid this, try to place the power and ground planes on the inner layers of the board and align components in a symmetrical manner. In addition, avoid forming 90-degree trace angles.

Place power and ground planes in the inner layers of the board

When designing a circuit board, it is important to place power and ground planes in the inner layers. This helps minimize the amount of EMI, which can result from the proximity of high-speed signals to a ground plane. Ground planes are also necessary for reducing the amount of volt drop on a power rail. By placing power and ground planes in the inner layers, you can make room on the signal layers.

Once you’ve made sure that the power and ground planes are in the inner layers, you can move onto the next step of the process. In the Layer Stack Manager, add a new plane and assign a network label to it. After the network label is assigned, double-click on the layer. Be sure to consider the distribution of components, such as I/O ports. You also want to keep the GND layer intact.

Avoid soldering with your face directly above the joint

Soldering with your face directly above the joint is a bad practice because the solder will lose heat to the ground plane and you’ll end up with a brittle joint. It can also cause a lot of problems, including excessive buildup on the pin. To avoid this, make sure that the pins and pads are both evenly heated.

The best way to avoid soldering with your face directly above a joint is to use flux. This helps transfer heat, and it also cleans the metal surface. Using flux also makes the solder joint smoother.

Place components with the same orientation

When laying out a PCB layout, it’s important to place components with the same orientation from the soldering angle. This will ensure proper routing and an error-free soldering process. It also helps to place surface mount devices on the same side of the board, and through-hole components on the top side.

The first step in laying out a layout is to locate all the components. Typically, components are placed outside the square outline, but this does not mean that they cannot be placed inside. Next, move each piece into the square outline. This step helps you understand how components are connected.

Avoid creating 90-degree trace angles

When designing a PCB layout, it is important to avoid creating 90-degree trace angles. These angles result in narrower trace width and increased risks of shorting. If possible, try to use 45-degree angles instead. These are also easier to etch and can save you time.

Creating 45-degree angle traces on your PCB layout will not only look better, but it will also make the life of your PCB manufacturer easier. It also makes copper etching easier.

Using 45-degree angles for etching

Using 45-degree angles for solder in PCB layout design is not a common practice. In fact, it’s a bit of a relic from the past. Historically, circuit boards have had right-angled corners and a lack of any solder mask. This is because early circuit boards were made without solder masks, and the process involved a process called photosensitization.

The problem with using angles larger than 90 degrees is that they tend to lead to copper migration and acid traps. Likewise, traces drawn on a layout at a right angle do not get as much etching. In addition, 90-degree angles can create partially traced angles, which can result in shorts. Using 45-degree angles is not only easier but safer, and will result in a cleaner and more accurate layout.

Choosing the appropriate package size

When planning a PCB layout, you must pay attention to the soldering angle and package size of the components on the board. This will help you minimize shadow effect problems. Typically, solder pads must be spaced at least 1.0mm apart. Also, be sure that through-hole components are placed on the top layer of the board.

The orientation of the components is another important factor. If the components are heavy, they should not be placed in the center of the PCB. This will reduce board deformation during the soldering process. Place smaller devices near the edges, while larger ones should be placed on the top or bottom side of the PCB. For example, polarized components should be aligned with positive and negative poles on one side. Also, be sure to place taller components next to smaller ones.

Three Tips For Reducing PCB Design Risk

Three Tips For Reducing PCB Design Risk

There are many ways to reduce the risk associated with PCB design. Some of these include orienting all components in the same direction and using multiple vias at layer transitions. Others include keeping analog and digital circuits separate and keeping oscillatory circuits away from heat.

Orienting components in the same direction

PCB design risk is minimized by orienting components in the same direction. This practice helps minimize assembly and handling time, and reduces rework and costs. Orienting components in the same direction also helps reduce the likelihood of a component being rotated 180 degrees during testing or assembly.

Orientation of components starts with footprint construction. An incorrect footprint can lead to miss-connected parts. For example, if a diode is oriented with its cathode pointing in one direction, the cathode could be connected to the wrong pin. Also, multiple-pin parts can be installed in the wrong orientation. This can cause the parts to float on the pads or stand up, which causes a tombstoning effect.

In older circuit boards, the majority of components were oriented in one direction. However, modern circuit boards must take into account signals that move at high speeds and are subject to power integrity concerns. In addition, thermal considerations must be addressed. As a result, layout teams must balance electrical performance and manufacturability.

Using multiple vias at layer transitions

While it is not possible to eliminate vias at layer transitions completely, it is possible to minimize the radiation from them by using stitching vias. These vias should be close to the signal vias to minimize the distance the signal travels. It is important to avoid coupling in these vias, as this compromises the integrity of the signal while in transit.

Another way to reduce PCB design risk is to use multiple vias at layer transitions. This reduces the number of pins on a PCB and improves mechanical strength. It also helps reduce parasitic capacitance, which is particularly important when dealing with high frequencies. Additionally, using multiple vias at layer transitions also allows you to use differential pairs and high-pin-count parts. However, it is important to keep the number of parallel signals low, in order to minimize signal coupling, crosstalk, and noise. It is also recommended to route noise signals separately on separate layers in order to reduce signal coupling.

Keeping heat away from oscillatory circuits

One of the most important things to keep in mind when designing a PCB is to keep the temperature as low as possible. Achieving this requires careful geometrical arrangement of components. It is also important to route high-current traces away from thermally sensitive components. The thickness of the copper traces also plays a role in PCB thermal design. The copper trace thickness should provide a low impedance path for current, as high resistance can cause significant power loss and heat generation.

Keeping heat away from oscillatory circuitry is a critical part of the PCB design process. For optimum performance, oscillator components should be placed near the center of the board, not near the edges. Components near the edges of the board tend to accumulate a lot of heat, and this can raise the local temperature. To reduce this risk, high-power components should be located in the center of the PCB. Furthermore, high-current traces should be routed away from the sensitive components, since they can cause the heat to accumulate.

Avoiding electrostatic discharge

Avoiding electrostatic discharge while designing PCBs is an essential aspect of electronic engineering. Electrostatic discharge can damage the precision semiconductor chips inside your circuit. It can also melt bonding wires and short-circuit PN junctions. Luckily, there are many technical methods to avoid this problem, including proper layout and layering. Most of these methods can be carried out with very little modification to your design.

First, you should understand how ESD works. In a nutshell, ESD causes a massive amount of current to flow. This current travels to the ground through the metal chassis of the device. In some cases, the current can follow multiple paths to the ground.

PCBA Pseudo-juottamisen syyt ja ratkaisut

PCBA Pseudo-juottamisen syyt ja ratkaisut

PCBA pseudo soldering is a problem that affects the quality of the finished PCBA. It can cause losses due to rework, which reduces the production efficiency. However, detecting and solving pseudo soldering problems can be done using inspection.

Reflow-juottaminen

Reflow soldering is one of the most common methods of PCB assembly. This method is often combined with wave soldering. It can greatly affect the quality of the assembled board, which is why the process requires a proper understanding of PCB construction.

To ensure a quality solder joint, it is important to follow several guidelines. First, it is important to check the alignment of the printed board. Make sure that the print is properly aligned before applying the solder paste. Second, clean the stencil bottom regularly. Third, reflow soldering can result in a tombstone effect, otherwise known as the Manhattan effect. The tombstone effect is caused by force imbalances during the reflow soldering process. The end result looks like a tombstone in a cemetery. In reality, the tombstone effect is an open circuit on a defunct PCB.

During the preheat stage, a small portion of the solder paste can gasify. This can cause a small amount of solder to leave the soldering pad, especially under chip components. In addition, melted solder paste may push out under sheet-type resistor-capacitor units.

Wave soldering

PCB assembly process defects, including tombstoning, occur in a variety of ways. One of the main causes is inadequate soldering quality. Poor soldering results in cracks that appear on the surface of discrete components. These defects can be easily corrected with rework, although they can create a wide range of problems in the assembly process.

PCB manufacturers need to be aware of these defects to prevent them from occurring in the production process. These defects may be hard to detect, but different technologies and methods can help detect them and minimize their impact. These methods allow manufacturers to prevent soldering defects before they occur and help them produce high-quality products.

Stencil thickness

PCB pseudo-soldering can be caused by a number of factors. For example, an incorrect stencil can lead to over-applied solder paste on the components. Moreover, a poorly shaped stencil can result in solder balling or discrete deformities. These issues can be resolved by reducing the thickness of the stencil or the aperture size. However, these steps should be done with caution because even the slightest undersizing can lead to major problems in later PCB assembly stages.

PCB pseudo-soldering can be prevented by properly applying flux. Flux is a thixotropic agent that makes solder paste have pseudo-plastic flow characteristics. This means that it will reduce in viscosity when passing through the stencil’s apertures, but will recover once the external force is removed. The amount of flux used in solder paste should be eight to fifteen percent. Lower values will result in a thin solder film, while higher ones will cause excessive deposits.

Squeegee pressure

PCBA pseudo soldering, also known as cold soldering, is an in-between stage of the soldering process in which a portion of the board is not fully soldered. This can compromise the quality of the PCB board and affect its circuit characteristics. This defect may result in the scrapping or disqualification of the PCB board.

To control the squeegee pressure can solve the problem of pseudo soldering. Too much pressure will smear the solder paste and cause it to spread across the PCB’s flat surface. Alternatively, too little pressure will cause the solder paste to scoop up into larger apertures, causing the PCB to be covered with too much paste.

PCB Plug -mekanismin ja tehokkaan ohjausmenetelmän tutkimus

PCB Plug -mekanismin ja tehokkaan ohjausmenetelmän tutkimus

Paineistetut mikrokammiot

Paineistettu mikrokammio on tehokas keino kuljettaa nestettä lab-on-PCB-laitteissa. Se toimii varastoimalla pneumaattista energiaa ja vapauttamalla sen mikroventtiilin aukon kautta. Mikroventtiili aktivoidaan sähköisesti käyttämällä halkaisijaltaan noin 25 metrin pituista kultalankaa.

Lab-on-PCB-laitteita kehitetään parhaillaan monenlaisia biolääketieteellisiä sovelluksia varten, mutta niitä ei ole vielä kaupallisesti saatavilla. Alan tutkimus kuitenkin lisääntyy nopeasti, ja markkinakelpoisten laitteiden saaminen markkinoille on mahdollista. On kehitetty erilaisia virtausta ohjaavia menetelmiä, kuten dielektristen materiaalien sähköistäminen, elektroosmoottinen virtauksen ohjaaminen ja faasimuutokseen perustuva virtauksen ohjaaminen.

Ulkoisten lähteiden käyttöä nesteiden liikuttamiseen laboratorio-PCB-järjestelmissä on käytetty jo pitkään tutkimuksessa, mutta se ei ole erityisen käytännöllinen ratkaisu kannettavassa järjestelmässä. Ulkoiset ruiskupumput vähentävät myös laitteen siirrettävyyttä. Ne tarjoavat kuitenkin mielenkiintoisen mahdollisuuden integroida antureita ja toimilaitteita mikrofluidiseen laitteeseen.

Myös elektroosmoottisia pumppuja integroidaan yleisesti piirilevyihin nesteen käsittelyä varten. Ne tarjoavat edullisen, pulssittoman jatkuvan nestevirtauksen, mutta vaativat kapeita mikrokanavia ja ulkoisia nestesäiliöitä. Epäasianmukainen aktivointi voi johtaa elektrolyysiin ja mikrokanavien tukkeutumiseen. Kuparielektrodit eivät myöskään ole ihanteellisia, koska ne voivat aiheuttaa nesteen saastumista ja mikrokanavien tukkeutumista. Lisäksi kuparielektrodit vaativat ylimääräisiä valmistusvaiheita ja lisäävät kustannuksia.

Laboratory-on-PCBs

Laboratory-on-PCBs (LoP) on laitetyyppi, joka integroi elektronisen piirin piirilevylle. Tämäntyyppistä laitetta käytetään erilaisten elektroniikkapiirejä koskevien kokeiden suorittamiseen. Sitä käytetään myös sovelluksissa, jotka edellyttävät eri materiaalien integrointia. Nämä laitteet ovat yhteensopivia virtausajotekniikoiden kanssa, ja ne voidaan valmistaa myös fotolitografia- tai kuivaresistimenetelmillä. Lisäksi nämä laitteet sisältävät myös pinta-asennettuja elektronisia komponentteja, jotka on suunniteltu mittaamaan tietoja. Yksi tällainen esimerkki on laite, johon on integroitu sininen LED ja integroitu lämpötila-anturi.

Toinen vaihtoehto nesteiden siirtämiseen Lab-on-PCB:ssä on käyttää paineistettuja mikrokammioita. Paineistetut kammiot voivat varastoida pneumaattista energiaa, ja ne voidaan vapauttaa avaamalla mikroventtiili. Mikroventtiilit aktivoidaan sähköisesti. Tämäntyyppisen mekanismin etuna on, että se on kannettava ja sitä voidaan käyttää useita kertoja. Lisäksi se kestää korkeita paineita.

Yksi tärkeimmistä haasteista mikroventtiilien toteuttamisessa piirilevyihin on niiden integroinnin vaikeus piirilevyyn. Myös liikkuvia osia sisältäviä toimilaitteita on vaikea integroida piirilevyyn. Tutkijat ovat kuitenkin kehittäneet piirilevypohjaisia mikropumppuja, joissa on käytetty pietsosähköisiä toimilaitteita.

Lab-on-PCB:n käyttö nesteiden valvontaan on erittäin monimutkaista ja voi olla melko vaikeaa. Menetelmässä on lukuisia haittoja, ja suurin vaikeus on monimutkainen valmistusprosessi. Lisäksi LoP:ien kokoamismenetelmä lisää myös laitteen monimutkaisuutta.