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PCBTok's Perfectly Constructed Charger PCB
Over a thousand customers worldwide have expressed satisfaction with PCBTok’s Charger PCB, which has received worldwide recognition for its fineness and ability to function flawlessly at its highest efficiency.
- Prior to production, all files are carefully checked by CAM.
- All necessary inspections are carried out without fail (E-Test and AOI).
- 24/7 availability of professional assistance.
- With your personalized Charger PCB, you get our complete support.
- There are approximately 500 people working in our facility.
Highly Reliable Charger PCB Products from PCBTok
We have been providing durable and reliable Charger PCB to customers globally without any problems owing to the assistance of our skilled professionals.
All that we offer to our customers is the best. PCBTok constantly aims to satisfy the needs of its customers by providing them with quality Charger PCB.
In addition, we are more than capable of producing all kinds of Charger PCB depending on your desired applications at a very reasonable price.
PCBTok’s always passionate about fulfilling your demands without experiencing any flaws.
Furthermore, PCBTok has complied with the necessary accreditations required by the international guidelines to produce the greatest Charger PCB; RoHS, CE, ISO, etc.
Charger PCB By Feature
The Fast Charger PCB has gained a lot of popularity nowadays because of the fast-paced industry that a lot of people belong. Through this, you can quickly charge your device within minutes and use it for a long period of time.
The Wireless Charger PCB has also become popular among most consumers since it is way more convenient than carrying a device with a lot of cables. In addition, this type of charger has been widely used in modern automobiles.
The USB Car Charger PCB has quite the similarity with the wireless one in cars; however, instead of the wireless way, it uses traditional charging. Through a USB cable to another type of USB to connect devices.
The Solar Power Bank Charger PCB has been recognized in modern technology because of its efficiency. It is able to convert the sun rays that it touches into electricity that can power certain devices.
The Customized Charger PCB is ideal if you’re seeking to have your own freedom in terms of designing the overall product. In addition, this can be a great alternative if you have some personalized project that needs a Charger PCB.
The Mobile Charger PCB is the most common type we see daily in our household. In addition, this type of Charger PCB can power our mobile device through the help of an adaptor and a USB to USB cable plugged into a power source.
Charger PCB By Base Material (5)
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The FR-4 Charger PCB is the most popular type of base material because of its inexpensive cost a greater amount of benefits on it. It offers good electrical insulation with better dielectric strength and, resistance to moisture.
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The Fiberglass Epoxy Charger PCB is an ideal selection for a base material if you’re seeking for a cheaper alternative. Despite its inexpensive price, it has certain benefits such as its capability to be re-used.
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The Polyimide Resin Charger PCB base material is commonly combined with the fiberglass epoxy. In addition, a Polyimide material has a high resistance to chemicals, and it has exceptional electrical properties.
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The Aluminum Charger PCB offers great stability to the device. In addition, it is not that expensive despite its numerous strengths; thus, they are widely used in most power converters and power supply devices.
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The Copper Charger PCB is recognized in the industry for its conductivity; it is capable of transmitting signals without experiencing the loss of electricity. Thus, they can be frequently found in most Wireless Charger PCBs.
Charger PCB By Surface Finish (5)
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The ENIG Charger PCB is recognized to be ecological since it doesn’t use any lead, and it is a halogen-free finish. Also, if you’re planning to incorporate a through-hole, this is the perfect option. However, it cannot be reworked.
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The Immersion Silver Charger PCB can be a good alternative for the ENIG surface finish. Also, this type of finish is cost-effective, RoHS compliant offers good stability to the overall board, and it has a longer shelf-life.
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The OSP Charger PCB is known to be a water-based finish; thus, it can be safely attached to copper pads. This type of finish is lead-free, and can be re-worked, so it can save you some costs in the long-run of utilization this finish.
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The Lead-Free HASL Charger PCB, as its name indicates, it doesn’t use any lead content on it; thus, making it ecologically friendly. Moreover, it is durable, re-workable, widely available, and relatively inexpensive.
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The ENEPIG Charger PCB is also termed a “universal finish” since it can be applied to any type of board. In addition, it is compatible with solders such as tin, silver, and copper. However, it can be expensive to produce.
Charger PCB Benefits
PCBTok can offer 24h online support for you. When you have any PCB-related questions, please feel free to get in touch.
PCBTok can build your PCB prototypes quickly. We also provide 24 hour production for quick-turn PCBs at our facility.
We often ship goods by international forwarders such as UPS, DHL, and FedEx. If they are urgent, we use priority express service.
PCBTok has passed ISO9001 and 14001, and also has USA and Canada UL certifications. We strictly follow IPC class 2 or class 3 standards for our products.
Advantages of Charger PCB in your Operations
It’s important to consider a product’s perks for your applications prior to making a purchase. An advantage of a Charger PCB is as follows:
- Cost – It can save you a lot since there’s no need to replace a battery in a device because you can always re-charge it anytime.
- Safety – If plan to deploy a wireless one, it can minimize the risk of short circuits.
- Convenience – Most Charger PCB types don’t use that many cables such as for the wireless type of charger.
The Charger PCB has more to offer depending on the type of product you might want to use, apart from these. Just ping us for more details about our Charger PCB.
Features of PCBTok’s Charger PCB
You can take advantage of the following features of PCBTok’s Charger PCB in your application:
- Detection – It has enhanced accuracy in terms of detecting voltage circuits.
- Lifespan – It can operate for up to 50,000 hours.
- Durability – We guarantee improved craftsmanship that makes it reliable.
- Protections – We offer various protections for your Charger PCB; overcharge, short circuit, over-current, and over-discharge.
Send us a note if you would like additional information about the features of our Charger PCB on PCBTok, and we will get back to you right away.
Factors to Consider in Customization of Battery Charger PCB
If you intend to customize your Battery Charger PCB, you might wish to take into account the following widely available batteries:
- Nickel-Metal Hybrid Battery (NiMH) – It is recommended to look at its battery leakage, charging cycle, battery position, and current flow regulation.
- Nickel Cadmium Battery (NiCd) – This requires constant checking of the current and consistent count of charge and discharge cycle.
- Lithium-Ion Polymer Battery (LiPo) – This requires constant current since it can be prone to overheat, and constant checking of the battery temperature.
To learn more specifically about these batteries, you can write us a message.
PCBTok is an Expert at Providing Superior Charger PCB
As a Charger PCB manufacturer with more than ten years of expertise, PCBTok is well-versed in offering high-quality PCB goods to the market. We are more than equipped to meet your Charger PCB requirements.
In order to ensure that the Charger PCB manufacturer you choose is competent, it is crucial to look for a business with significant industry experience.
In addition, PCBTok’s a manufacturer that can meet certain deadlines without compromising the quality of the product. Hence, you can assure that your entire product requirements are met, and will be sent out to you on time without any flaws.
We are a company that values integrity and prioritizes our customer’s needs; we always make sure to provide you only the best Charger PCB products.
Charger PCB Fabrication
In designing your Charger PCB, there are a lot of things to consider in achieving a perfect result. These are the following phases we take in designing your product.
The process of designing a Charger PCB goes through a Schematic Design, PCB Layout, Component Placement, and Routing and Connection.
Each of these phases is crucial in determining the performance of your Charger PCB; thus, in PCBTok, we are always careful in performing these stages.
We only deploy the most skilled personnel to perform this in your product to guarantee that you will receive a flawless and highly functioning Charger PCB product.
Just direct message us for in-depth information about this.
In order to achieve a quality and flawless Charger PCB, we always consider the laminates of the board. We deploy six basic materials on it to guarantee they’ll perform their optimum performance.
The Charger PCB foundation materials are the following; prepreg, laminate, copper foil, solder mask, nomenclature, and aluminum board.
All of these are crucial in constructing your Charger PCB. In PCBTok, we only use materials that are high-quality to guarantee a top-notch byproduct.
Furthermore, after combining all of the foundation materials, we will run it through several tests to guarantee its durability and reliability during its operation.
For a more detailed explanation of each laminate, just mail us directly.
OEM & ODM Charger PCB Applications
In modern times, most cars already have their own dedicated charging slot that is powered through the help of the automotives’ battery; from wired charging to wireless.
Due to the rise of expenses in the current times, many people prefer power generation devices that are re-chargeable since they can save a huge amount of money.
One of the advantages of a Charger PCB nowadays is that it can be easily carried such as for laptops; thus, they are becoming useful in the industry.
In the communications industry, they are switching more onto wireless technologies for much more efficient and convenient work; a Charger PCB has become handy.
Most medical instruments nowadays can be carried anytime and anywhere for faster diagnosis and health evaluation; all of it has been made possible through a Charger PCB.
Charger PCB Production Details As Following Up
- Production Facility
- PCB Capabilities
- Shipping Methods
- Payment Methods
- Send Us Inquiry
| NO | Item | Technical Specification | ||||||
| Standard | Advanced | |||||||
| 1 | Layer Count | 1-20 layers | 22-40 layer | |||||
| 2 | Base Material | KB、Shengyi、ShengyiSF305、FR408、FR408HR、IS410、FR406、GETEK、370HR、IT180A、Rogers4350、Rogers400、PTFE Laminates(Rogers series、Taconic series、Arlon series、Nelco series)、Rogers/Taconic/Arlon/Nelco laminate with FR-4 material(including partial Ro4350B hybrid laminating with FR-4) | ||||||
| 3 | PCB Type | Rigid PCB/FPC/Flex-Rigid | Backplane、HDI、High multi-layer blind&buried PCB、Embedded Capacitance、Embedded resistance board 、Heavy copper power PCB、Backdrill. | |||||
| 4 | Lamination type | Blind&buried via type | Mechanical blind&burried vias with less than 3 times laminating | Mechanical blind&burried vias with less than 2 times laminating | ||||
| HDI PCB | 1+n+1,1+1+n+1+1,2+n+2,3+n+3(n buried vias≤0.3mm),Laser blind via can be filling plating | 1+n+1,1+1+n+1+1,2+n+2,3+n+3(n buried vias≤0.3mm),Laser blind via can be filling plating | ||||||
| 5 | Finished Board Thickness | 0.2-3.2mm | 3.4-7mm | |||||
| 6 | Minimum Core Thickness | 0.15mm(6mil) | 0.1mm(4mil) | |||||
| 7 | Copper Thickness | Min. 1/2 OZ, Max. 4 OZ | Min. 1/3 OZ, Max. 10 OZ | |||||
| 8 | PTH Wall | 20um(0.8mil) | 25um(1mil) | |||||
| 9 | Maximum Board Size | 500*600mm(19”*23”) | 1100*500mm(43”*19”) | |||||
| 10 | Hole | Min laser drilling size | 4mil | 4mil | ||||
| Max laser drilling size | 6mil | 6mil | ||||||
| Max aspect ratio for Hole plate | 10:1(hole diameter>8mil) | 20:1 | ||||||
| Max aspect ratio for laser via filling plating | 0.9:1(Depth included copper thickness) | 1:1(Depth included copper thickness) | ||||||
| Max aspect ratio for mechanical depth- control drilling board(Blind hole drilling depth/blind hole size) |
0.8:1(drilling tool size≥10mil) | 1.3:1(drilling tool size≤8mil),1.15:1(drilling tool size≥10mil) | ||||||
| Min. depth of Mechanical depth-control(back drill) | 8mil | 8mil | ||||||
| Min gap between hole wall and conductor (None blind and buried via PCB) |
7mil(≤8L),9mil(10-14L),10mil(>14L) | 5.5mil(≤8L),6.5mil(10-14L),7mil(>14L) | ||||||
| Min gap between hole wall conductor (Blind and buried via PCB) | 8mil(1 times laminating),10mil(2 times laminating), 12mil(3 times laminating) | 7mil(1 time laminating), 8mil(2 times laminating), 9mil(3 times laminating) | ||||||
| Min gab between hole wall conductor(Laser blind hole buried via PCB) | 7mil(1+N+1);8mil(1+1+N+1+1 or 2+N+2) | 7mil(1+N+1);8mil(1+1+N+1+1 or 2+N+2) | ||||||
| Min space between laser holes and conductor | 6mil | 5mil | ||||||
| Min space between hole walls in different net | 10mil | 10mil | ||||||
| Min space between hole walls in the same net | 6mil(thru-hole& laser hole PCB),10mil(Mechanical blind&buried PCB) | 6mil(thru-hole& laser hole PCB),10mil(Mechanical blind&buried PCB) | ||||||
| Min space bwteen NPTH hole walls | 8mil | 8mil | ||||||
| Hole location tolerance | ±2mil | ±2mil | ||||||
| NPTH tolerance | ±2mil | ±2mil | ||||||
| Pressfit holes tolerance | ±2mil | ±2mil | ||||||
| Countersink depth tolerance | ±6mil | ±6mil | ||||||
| Countersink hole size tolerance | ±6mil | ±6mil | ||||||
| 11 | Pad(ring) | Min Pad size for laser drillings | 10mil(for 4mil laser via),11mil(for 5mil laser via) | 10mil(for 4mil laser via),11mil(for 5mil laser via) | ||||
| Min Pad size for mechanical drillings | 16mil(8mil drillings) | 16mil(8mil drillings) | ||||||
| Min BGA pad size | HASL:10mil, LF HASL:12mil, other surface technics are 10mil(7mil is ok for flash gold) | HASL:10mil, LF HASL:12mil, other surface technics are 7mi | ||||||
| Pad size tolerance(BGA) | ±1.5mil(pad size≤10mil);±15%(pad size>10mil) | ±1.2mil(pad size≤12mil);±10%(pad size≥12mil) | ||||||
| 12 | Width/Space | Internal Layer | 1/2OZ:3/3mil | 1/2OZ:3/3mil | ||||
| 1OZ: 3/4mil | 1OZ: 3/4mil | |||||||
| 2OZ: 4/5.5mil | 2OZ: 4/5mil | |||||||
| 3OZ: 5/8mil | 3OZ: 5/8mil | |||||||
| 4OZ: 6/11mil | 4OZ: 6/11mil | |||||||
| 5OZ: 7/14mil | 5OZ: 7/13.5mil | |||||||
| 6OZ: 8/16mil | 6OZ: 8/15mil | |||||||
| 7OZ: 9/19mil | 7OZ: 9/18mil | |||||||
| 8OZ: 10/22mil | 8OZ: 10/21mil | |||||||
| 9OZ: 11/25mil | 9OZ: 11/24mil | |||||||
| 10OZ: 12/28mil | 10OZ: 12/27mil | |||||||
| External Layer | 1/3OZ:3.5/4mil | 1/3OZ:3/3mil | ||||||
| 1/2OZ:3.9/4.5mil | 1/2OZ:3.5/3.5mil | |||||||
| 1OZ: 4.8/5mil | 1OZ: 4.5/5mil | |||||||
| 1.43OZ(positive):4.5/7 | 1.43OZ(positive):4.5/6 | |||||||
| 1.43OZ(negative ):5/8 | 1.43OZ(negative ):5/7 | |||||||
| 2OZ: 6/8mil | 2OZ: 6/7mil | |||||||
| 3OZ: 6/12mil | 3OZ: 6/10mil | |||||||
| 4OZ: 7.5/15mil | 4OZ: 7.5/13mil | |||||||
| 5OZ: 9/18mil | 5OZ: 9/16mil | |||||||
| 6OZ: 10/21mil | 6OZ: 10/19mil | |||||||
| 7OZ: 11/25mil | 7OZ: 11/22mil | |||||||
| 8OZ: 12/29mil | 8OZ: 12/26mil | |||||||
| 9OZ: 13/33mil | 9OZ: 13/30mil | |||||||
| 10OZ: 14/38mil | 10OZ: 14/35mil | |||||||
| 13 | Dimension Tolerance | Hole Position | 0.08 ( 3 mils) | |||||
| Conductor Width(W) | 20% Deviation of Master A/W |
1mil Deviation of Master A/W |
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| Outline Dimension | 0.15 mm ( 6 mils) | 0.10 mm ( 4 mils) | ||||||
| Conductors & Outline ( C – O ) |
0.15 mm ( 6 mils) | 0.13 mm ( 5 mils) | ||||||
| Warp and Twist | 0.75% | 0.50% | ||||||
| 14 | Solder Mask | Max drilling tool size for via filled with Soldermask (single side) | 35.4mil | 35.4mil | ||||
| Soldermask color | Green, Black, Blue, Red, White, Yellow,Purple matte/glossy | |||||||
| Silkscreen color | White, Black,Blue,Yellow | |||||||
| Max hole size for via filled with Blue glue aluminium | 197mil | 197mil | ||||||
| Finish hole size for via filled with resin | 4-25.4mil | 4-25.4mil | ||||||
| Max aspect ratio for via filled with resin board | 8:1 | 12:1 | ||||||
| Min width of soldermask bridge | Base copper≤0.5 oz、Immersion Tin: 7.5mil(Black), 5.5mil(Other color) , 8mil( on copper area) | |||||||
| Base copper≤0.5 oz、Finish treatment not Immersion Tin : 5.5 mil(Black,extremity 5mil), 4mil(Other color,extremity 3.5mil) , 8mil( on copper area |
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| Base coppe 1 oz: 4mil(Green), 5mil(Other color) , 5.5mil(Black,extremity 5mil),8mil( on copper area) | ||||||||
| Base copper 1.43 oz: 4mil(Green), 5.5mil(Other color) , 6mil(Black), 8mil( on copper area) | ||||||||
| Base copper 2 oz-4 oz: 6mil, 8mil( on copper area) | ||||||||
| 15 | Surface Treatment | Lead free | Flash gold(electroplated gold)、ENIG、Hard gold、Flash gold、HASL Lead free、OSP、ENEPIG、Soft gold、Immersion silver、Immersion Tin、ENIG+OSP,ENIG+Gold finger,Flash gold(electroplated gold)+Gold finger,Immersion silver+Gold finger,Immersion Tin+Gold finge | |||||
| Leaded | Leaded HASL | |||||||
| Aspect ratio | 10:1(HASL Lead free、HASL Lead、ENIG、Immersion Tin、Immersion silver、ENEPIG);8:1(OSP) | |||||||
| Max finished size | HASL Lead 22″*39″;HASL Lead free 22″*24″;Flash gold 24″*24″;Hard gold 24″*28″;ENIG 21″*27″;Flash gold(electroplated gold) 21″*48″;Immersion Tin 16″*21″;Immersion silver 16″*18″;OSP 24″*40″; | |||||||
| Min finished size | HASL Lead 5″*6″;HASL Lead free 10″*10″;Flash gold 12″*16″;Hard gold 3″*3″;Flash gold(electroplated gold) 8″*10″;Immersion Tin 2″*4″;Immersion silver 2″*4″;OSP 2″*2″; | |||||||
| PCB thickness | HASL Lead 0.6-4.0mm;HASL Lead free 0.6-4.0mm;Flash gold 1.0-3.2mm;Hard gold 0.1-5.0mm;ENIG 0.2-7.0mm;Flash gold(electroplated gold) 0.15-5.0mm;Immersion Tin 0.4-5.0mm;Immersion silver 0.4-5.0mm;OSP 0.2-6.0mm | |||||||
| Max high to gold finger | 1.5inch | |||||||
| Min space between gold fingers | 6mil | |||||||
| Min block space to gold fingers | 7.5mil | |||||||
| 16 | V-Cutting | Panel Size | 500mm X 622 mm ( max. ) | 500mm X 800 mm ( max. ) | ||||
| Board Thickness | 0.50 mm (20mil) min. | 0.30 mm (12mil) min. | ||||||
| Remain Thickness | 1/3 board thickness | 0.40 +/-0.10mm( 16+/-4 mil ) | ||||||
| Tolerance | ±0.13 mm(5mil) | ±0.1 mm(4mil) | ||||||
| Groove Width | 0.50 mm (20mil) max. | 0.38 mm (15mil) max. | ||||||
| Groove to Groove | 20 mm (787mil) min. | 10 mm (394mil) min. | ||||||
| Groove to Trace | 0.45 mm(18mil) min. | 0.38 mm(15mil) min. | ||||||
| 17 | Slot | Slot size tol.L≥2W | PTH Slot: L:+/-0.13(5mil) W:+/-0.08(3mil) | PTH Slot: L:+/-0.10(4mil) W:+/-0.05(2mil) | ||||
| NPTH slot(mm) L+/-0.10 (4mil) W:+/-0.05(2mil) | NPTH slot(mm) L:+/-0.08 (3mil) W:+/-0.05(2mil) | |||||||
| 18 | Min Spacing from hole edge to hole edge | 0.30-1.60 (Hole Diameter) | 0.15mm(6mil) | 0.10mm(4mil) | ||||
| 1.61-6.50 (Hole Diameter) | 0.15mm(6mil) | 0.13mm(5mil) | ||||||
| 19 | Min spacing between hole edge to circuitry pattern | PTH hole: 0.20mm(8mil) | PTH hole: 0.13mm(5mil) | |||||
| NPTH hole: 0.18mm(7mil) | NPTH hole: 0.10mm(4mil) | |||||||
| 20 | Image transfer Registration tol | Circuit pattern vs.index hole | 0.10(4mil) | 0.08(3mil) | ||||
| Circuit pattern vs.2nd drill hole | 0.15(6mil) | 0.10(4mil) | ||||||
| 21 | Registration tolerance of front/back image | 0.075mm(3mil) | 0.05mm(2mil) | |||||
| 22 | Multilayers | Layer-layer misregistration | 4layers: | 0.15mm(6mil)max. | 4layers: | 0.10mm(4mil) max. | ||
| 6layers: | 0.20mm(8mil)max. | 6layers: | 0.13mm(5mil) max. | |||||
| 8layers: | 0.25mm(10mil)max. | 8layers: | 0.15mm(6mil) max. | |||||
| Min. Spacing from Hole Edge to Innerlayer Pattern | 0.225mm(9mil) | 0.15mm(6mil) | ||||||
| Min.Spacing from Outline to Innerlayer Pattern | 0.38mm(15mil) | 0.225mm(9mil) | ||||||
| Min. board thickness | 4layers:0.30mm(12mil) | 4layers:0.20mm(8mil) | ||||||
| 6layers:0.60mm(24mil) | 6layers:0.50mm(20mil) | |||||||
| 8layers:1.0mm(40mil) | 8layers:0.75mm(30mil) | |||||||
| Board thickness tolerance | 4layers:+/-0.13mm(5mil) | 4layers:+/-0.10mm(4mil) | ||||||
| 6layers:+/-0.15mm(6mil) | 6layers:+/-0.13mm(5mil) | |||||||
| 8-12 layers:+/-0.20mm (8mil) | 8-12 layers:+/-0.15mm (6mil) | |||||||
| 23 | Insulation Resistance | 10KΩ~20MΩ(typical:5MΩ) | ||||||
| 24 | Conductivity | <50Ω(typical:25Ω) | ||||||
| 25 | Test voltage | 250V | ||||||
| 26 | Impedance control | ±5ohm(<50ohm), ±10%(≥50ohm) | ||||||
PCBTok offers flexible shipping methods for our customers, you may choose from one of the methods below.
1. DHL
DHL offers international express services in over 220 countries.
DHL partners with PCBTok and offers very competitive rates to customers of PCBTok.
It normally takes 3-7 business days for the package to be delivered around the world.
2. UPS
UPS gets the facts and figures about the world’s largest package delivery company and one of the leading global providers of specialized transportation and logistics services.
It normally takes 3-7 business days to deliver a package to most of the addresses in the world.
3. TNT
TNT has 56,000 employees in 61 countries.
It takes 4-9 business days to deliver the packages to the hands
of our customers.
4. FedEx
FedEx offers delivery solutions for customers around the world.
It takes 4-7 business days to deliver the packages to the hands
of our customers.
5. Air, Sea/Air, and Sea
If your order is of large volume with PCBTok, you can also choose
to ship via air, sea/air combined, and sea when necessary.
Please contact your sales representative for shipping solutions.
Note: if you need others, please contact your sales representative for shipping solutions.
You can use the following payment methods:
Telegraphic Transfer(TT): A telegraphic transfer (TT) is an electronic method of transferring funds utilized primarily for overseas wire transactions. It’s very convenient to transfer.
Bank/Wire transfer: To pay by wire transfer using your bank account, you need to visit your nearest bank branch with the wire transfer information. Your payment will be completed 3-5 business days after you have finished the money transfer.
Paypal: Pay easily, fast and secure with PayPal. many other credit and debit cards via PayPal.
Credit Card: You can pay with a credit card: Visa, Visa Electron, MasterCard, Maestro.
Related Products
Charger PCB – The Ultimate FAQ Guide
If you’ve heard the term “charger PCB” in the electronics field, then you’ve come to the right place. These PCBs are an important part of many electronic devices. You may be wondering what the term means. The answer varies from industry to industry, but it usually has to do with battery charging. We’ll look at some key terms and components to help you understand what a printed circuit board is.
UL Listed: To receive this certification, a battery charger PCB must pass a series of rigorous tests. This certification addresses the risks associated with using a battery charger and the performance of the battery charger under specified conditions. In addition to UL certification, battery charger PCBs must also be regulated under RoHS (Restriction of Hazardous Substances). If the battery charger PCB is not UL certified, it must pass additional testing to obtain RoHS certification.
The service life of the battery charger PCB varies depending on the size and type of equipment used. The service life of a battery charger PCB ranges from 3 to 14 working days, depending on its design capability and operating conditions. If a battery charger PCB is used and handled properly, it should last 50-70 years. This assumes that environmental conditions and manufacturer’s operating instructions are followed.