Your Reliable Single-Sided Flexible PCB Manufacturer in China

SMTFAB is a Professional single-sided flexible PCB supplier in China, and we can provide a one-stop solution for your project.

Over 12 years of single-sided flexible PCB manufacturing experience
Full range of single-sided flexible PCB raw material in stock
100% E-test and final inspection
No minimum order quantity for your new order
24h quick-turn service for your prototype single-sided flexible PCB
7/24 sales and engineering tech support

Send Your Inquiry Now

Production Facility
Flexible PCB Capabilities
1layer Flex PCB Stackup

For flexible PCB capabilities, please refer to the following form.

Feature		Capability
Number of Layers		1 – 10layers
Order Quantity		1pc – 10000+pcs
Board thickness(without stiffener)		0.002-0.2inch
Min. Board Size		0.2*0.4inch
Min. Board Size		9*14 inch
Build Time		2days – 5weeks
Material	FCCL (adhesive)	Shengyi SF305
	FCCL (adhesiveness)	Panasonic R-F775
		Taiflex MHK
		Dupont Pyralux AP
	Coverlay	Shengyi SF305C
		Taiflex FHK 1025&2035
	Adhesive	Taiflex BT
	PI stiffener	Taiflex MHK
	3M	9077&6677&9058
Others	Tolerance of single layer	±0.05mm
	Tolerance of double-layer (≤0.3mm)	±0.05mm
	Tolerance of multi-layer(<0.3mm)	±0.05mm
	Tolerance of multi-layer(0.3-0.8mm)	±0.1mm
	Impedance control tolerance	Single ended:±5Ω(≤50Ω);±10%(>50Ω)
		Differential Pairs: ±5Ω (≤50Ω);±10%(>50Ω)
	Min coverlay bridge	8mil
	Min bend radius of single layer	3-6 times of board thickness
	Min bend radius of double-layer	6-10 times of board thickness
	Min bend radius of multilayer	10-15 times of board thickness
	Min dynamic bend radius	20-40 times of board thickness
Inner layer	Min line width/spacing (12/18um copper)	3.0/3.2mil (loop lines 6.0/6.2mil)
	Min line width/spacing (35um copper)	4.0/4.0mil (loop lines 8.0/8.0mil)
	Min line width/spacing (70um copper)	6.0/6.5mil (loop lines 10/10.5mil)
	Max copper thickness	2oz
Outer layer	Min line width/spacing (18um copper)	3/3.2mil (loop lines 6/6mil)
	Min line width/spacing (35um copper)	4/4.5mil (loop lines 6/6mil)
	Min line width/spacing (70um copper)	6/7mil (loop lines 6/6mil)
	Min line width/spacing (105um copper)	10/13mil (loop lines 6/6mil)
	Max finished copper thickness	3OZ
Drilling	Min distance between via and conductors	6mil (<4 layer)
		8mil (4-6 layer)
		12mil (7-8 layer)
	Min mechanical drill hole	6mil
Solder mask	Solder mask color	Green/White/Black/Yellow
and silkscreen	Coverlay	Yellow、Black
	Min solder dam (base copper ≤ 1OZ)	4mil (green),8mil(solder dam on the large copper)
	Min clearance	3mil (part for 2.5mil)
	Silk color	White, Yellow
Surface treatment	Surface treatment	HASL, ENIG, ENEPIG, Electrolytic Nickel Gold, Soft gold, Hard gold,
		Immersion silver and OSP
	Mixed surface treatment	ENIG+OSP, ENIG+G/F
	Gold thickness (ENIG)	0.05-0.10um
	Nickel thickness (ENIG)	3-6um
	Gold thickness (ENEPIG)	0.05-0.10um
	Palladium thickness (ENEPIG)	0.05-0.15um
	Nick thickness (ENEPIG)	3-6um
	Electrolytic nickel thickness	3-6um
	Electrolytic gold thickness	0.05-0.10um
	Hard gold thickness (including lead)	0.1-1.5um
	OSP thickness	0.1-0.3um
	Immersion silver thickness	0.2-0.4um
Routing	Laser accuracy	±0.05mm
	Punch accuracy	±0.05mm–±0.15mm

Single-sided Flexible PCB stackup — Layering or “stack-up” of a single-sided flexible PCB

Releted Some Other PCBs

Why Choose SMTFAB for Your Single-Sided Flexible PCB

Single-sided flexible PCB or single-sided flex PCB is the most basic flexible circuit board. The technology of single-sided flexible PCB is also the most simple in the flex PCB industry.

As a leading single-sided flexible PCB manufacturer in China, SMTFAB can offer a turnkey solution for your project. From PCB design & layout, PCB fabrication to PCB assembly, all processes are in-house and not outsourcing.

The quality is under our control, meanwhile, we can assure the delivery time.

If you have one project that needs to be produced in a hurry, SMTFAB can help you to make it. We can produce the prototype of a single-sided flexible PCB within 24H and ship it by UPS, FedEx, or DHL.

Single-sided flexible PCB has one conductive copper layer and one coverlay.

The standard board thickness is 1/2mil to 3mil and the copper thickness is 1/3oz to 2oz.

We have full service for quick-turn jobs and state-of-the-art equipment. It can meet your complicated project deadlines and budgets.

There are many different applications for single-sided flexible PCB, such as bar code equipment, cameras, smartphones, GPS systems, motion systems, and Satellites.

Are you looking for a premier single-sided flexible PCB supplier? SMTFAB is your best choice. SMTFAB has over 500 workers in our workshop and the monthly capacity is 40,000 square meters.

When you have any single-sided flexible PCB inquiry, please send it to us.

Single-Sided Flexible PCB: The Ultimate FAQ Guide

In this guide, there’re many questions about single-sided flexible PCB. You will get the answers here, so please start to read them.

Single-Sided Flexible PCB

What Is a Single-Sided Flexible PCB?
How To Design a Single-Sided Flexible PCB?
What Is The Layout Of a Single-Sided Flexible PCB?
What Is The Stack-Up Of Single-Sided Flexible PCB?
What Are The Benefits Of Single-Sided Flexible PCB?
What Are The Materials Of Single-Sided Flexible PCB?
What Are The Applications Of Single-Sided Flexible PCB?
Flexible Circuits In Medical Products

What Is a Single-Sided Flexible PCB?

The most basic kind of flexible circuit is a single-sided flexible PCB, also known as a single-sided Flex PCB.

They’re made up of a lightweight dielectric film that’s been laminated to a single copper layer.

After that, the copper coating is chemically engraved to fit the circuit pattern style. For improved insulation and safety, polyimide cover layers may be added to the circuit board.

A single-sided flexible PCB is the type of circuit board that consists of a flexible polyimide film laminated to a thin sheet of copper.

This Circuit is also known as single-layer flex. Then The copper layer is chemically etched to produce a circuit pattern specific to your specific design requirements.

In this circuit, Polyimide coverlay is added for insulation and environmental protection of this circuit.

One conductive copper layer and bonded between two insulating layers of polyimide coverlay/copper/flex core is added in this layer. Flex Core Materials are :

Standard thicknesses: ½ mil to 3 mils in either adhesive or adhesiveness constructions.
Standard copper thicknesses: 1/3 oz to 2 oz in rolled annealed or electrodeposited formats.

Its Coverlays Standard thickness is1/2 mil to 2 mil polyimide, with 1/2 mil to 2 mil epoxy or acrylic adhesive.

Single-Sided Flexible PCB

How To Design a Single-Sided Flexible PCB?

A single conductive copper sheet is bonded between two insulation layers or one polyimide insulating layer, and an exposed side is used in the one-sided flexible PCB configuration.

After that, the circuit outline is carved out of the internal copper sheet using a chemical etching technique.

Components, cables, pins, and stiffeners may all be seen on single-sided flex PCB boards. Similarly, certain single-sided flexible PCBs feature a dual-access mechanism that enables access to the conductive material from both sides of the circuit.

This design purpose necessitates a compact PCB and specialized layers to create access for the single copper layer via the base material’s polyimide layer.

What Is The Layout Of a Single-Sided Flexible PCB?

Several considerations go into developing a modular PCB layout, from materials to vias. Here are several considerations to consider when you build the single-sided flexible PCB layout:

Always consider the operating environment in which the final product has to function. The layout design process and materials differ for non-extreme environments and extreme environments.
Bear in mind the perfect bend ratio, which is the relationship between the bend radius and the flexible circuit’s thickness. The greater the bend radius, the greater the risk of failure while flexing.
Conductor selection and optimum routing techniques are essential since the path that transmits electrical current from one point to another decides PCB efficiency. The conductor pattern can also be studied to determine how flexing affects it. Conductors can be routed as near as possible across bend zones.
Pad fillets are recommended where the pad diameter is larger than the connecting strand width because they increase etched yield and material power.
Attempt to remove tear relief. A relief slot and an expansive corner radius are two popular strategies for avoiding tears in flex circuits.
Choose between blind or buried vias carefully because they considerably affect the cost of the single-sided flexible PCB.
Use mechanical stiffeners with caution since they will stiffen the SMT, connector, and other places on your flexible PCB.
Regardingimpedance regulation and signal integrity, reference plane layers and shielding are critical. As a typical shielding form, solid copper improves the circuit’s rigidity and should be included in the thickness-to-bend radius analysis. Some shielding techniques, such as cross-hatching and silver ink, may be used to improve flexibility.
Maintain signal integrity and impedance control. The amount and speed at which electricity will flow down a trace are referred to as impedance. The proper operation of your signals and the entire circuit board is referred to as matching impedance. The traces’ width, the size of the paths in the reference plane layers, the thickness of the traces, and the distance between two tracks in various impedance applications are all variables that influence the impedance feature of a flexible circuit.
Before exposing the single-sided flexible circuit to extreme temperatures, it’s crucial to guarantee that all moisture has been eliminated. After baking, quickly process the flex circuits. If this isn’t practical, keep the circuits in a nitrogen chamber or a desiccant-filled sealed dry box.

Single-Sided Flexible PCB

What Is The Stack-Up Of Single-Sided Flexible PCB?

The requirements imposed on a single-sided flexible circuit stack layout must be met continuously over the product’s existence.

The material must also fit together with the other layers of the flexible circuit stack to maintain the simplicity of manufacturing and durability.

The primary layers of the flex circuit stack and their roles are defined in the following subsections.

Base Material

The lightweight polymer film that acts as the laminate’s basis is regarded as the base material.

It is liable for the bulk of the flexible circuit’s critical physical and electrical properties.

The base material contains many of the signature properties of adhesive-free circuit constructions.

Thinner materials are more flexible than thicker materials and are used in a wide variety of thicknesses.

The material hardness is proportional to the cube of the thickness, which means that doubling the thickness renders the material eight times stiffer and still deflects 1/8 as much under the same load.

Modern thin-film technology allows the production of ever-smaller circuitry at a lower cost and with greater efficiency.

Bonding Adhesive

Adhesives serve as a bonding agent for laminates, but they are still an essential component of the circuit’s dielectric structure.

A flexible PCB is produced with a laminate, which is a metal-clad film. Because of their lower temperature tolerance, adhesives often restrict laminate efficiency, particularly when polyimide is used as the base material.

Many adhesives have a lower temperature capacity than thermoplastic polyimides. Also, with elevated temperatures and loads, many of them can soften. The thermoplastic/thermoset polyimides that withstand movement are the best-performing modern products.

These laminates are sometimes referred to as adhesive-less because they are adhesives in the true sense.

Different thicknesses of adhesives are available. Its use usually determines the thickness of a material.

Different adhesive thicknesses are widely used to build cover layers to satisfy various copper foil thicknesses’ fill requirements. Thinner adhesives give the copper more stability to get it closer to the base film.

Thinner adhesives will also save money by running quicker at the converter and using less total material, which can be costly depending on the material formulations.

It’s not unusual for a certain adhesive thickness to be used to render a cover layer to satisfy the full specifications of a specific form of a circuit.

A particular copper-foil thickness might be named out for circuits of different copper-foil thicknesses. On the top and bottom of the trace, the same quantity of adhesive is usually applied.

Single-Sided Flexible PCB

Metal Foil

The most popular conductive material in a flexible laminate is a metal foil. It is the substance from which the circuit tracks are usually etched.

While standard flexible circuit laminates are made of rolled and annealed copper, a single-sided flexible circuit may be made from various metal foils of multiple thicknesses.

Copper alloy C110 is a popular choice for flexible PCB manufacturing. It’s copper with a low oxygen content that’s renowned for being more ductile.

It’s less vulnerable to damage while also remaining tough.

What Are The Benefits Of Single-Sided Flexible PCB?

In interconnection applications, the real benefits of flexible circuits compared to conventional cabling and rigid PCBs include:

Reduced cabling and wiring errors
Elimination of mechanical connectors
Enhanced design flexibility
Higher circuit density
More robust operating temperature range
Stronger signal quality
Improved reliability and impedance control
Size and weight reduction

Single-Sided Flexible PCB

What Are The Materials Of Single-Sided Flexible PCB?

Flexible circuits are created from a broad range of materials, including films, foils, and adhesives.

The components to use are heavily influenced by how and when the circuit would be constructed and used in the end.

A careful assessment of the various materials’ relative merits might be needed to choose the right option for a particular application.

Flexible circuits depend highly on the nature of base materials.

There are some excellent materials for making flexible circuits, but there is no perfect solution.

A material that has all of the benefits and none of the disadvantages does not exist.

Today, a standard flexible circuit consists of a thin base dielectric polyimide (PI) film with a thickness of about 50 to 125 microns.

Manufacturers have learned to handle these materials to have acceptable yields in high-volume environments, particularly in semi-automated and automated processes.

Flexible circuits with the measurements mentioned are routinely produced with good results and tolerances.

Stability

Dimensional stability is necessary for the flexible laminate. Both the producer and the consumer are concerned with shrinking or expanding a flex circuit base material during manufacturing.

There are some approaches to dealing with the consequences of dimensionally variable products.

New thin-film technologies offer promising flexible and thinner materials.

Thermal and Tear Resistance

The material used for flex circuits must tolerate average assembly process temperatures without degradation.

The EU has ordered a transition to lead-free soldering in Europe and has place restrictions on halogenated flame retardants.

Therefore, lead-free solders have reduced the material range for flexible circuits.

Many products have been reformulated or withdrawn as a consequence.

The majority of flex circuit constructions utilize soft, unreinforced base materials that are prone to tearing.

Given the thin and fragile design of flexible circuit base materials, tear-resistance is a crucial feature. There are construction methods that can be used to alleviate tearing problems.

Flexibility

Flexibility is an essential material characteristic that is often a key characteristic. Temperature extremes, varying from a hot cook stove to cryogenically frozen, may be imposed on single-sided PCB flexibility.

Flexibility is particularly essential at low temperatures, where most materials become brittle.

Flexibility criteria may often change based on the application, and different products can be evaluated in different ways.

Cost

Flexible circuits with a single side are more costly than rigid PCBs. Designers also seek out low-cost products.

However, bear in mind that although a new material might be less expensive, it may also necessitate different manufacturing.

It may also have a distinct design, which may be troublesome in certain situations.

A red coloration shows ED copper in certain places, and it is generally believed to be of more inferior quality. In some instances, black-colored copper is mistaken for black copper oxide.

Epoxies and acrylics have various storage and laminating requirements and function best in some areas, but they are not often approved due to preconceptions.

Electrical Characteristics

Electrical properties for flexible circuit materials can be adapted to the design’s efficiency specifications.

The loss tangent or dissipation factor (Df) and dielectric constant (Dk) should be minimal.

For a variety of high-voltage uses, high insulation resistance is a valuable property.

A low Dk/Df adhesive or bonding layer will help you save resources and space by reducing your polyimide’s thickness.

The adhesive is in direct contact with the conductor, acts as a dielectric, and contributes to electrical output.

Other implementations, such as those with higher capacitance, can have different specifications.

What Are The Applications Of Single-Sided Flexible PCB?

There are two elementary types of applications of flexible circuits.

Static Applications

This type is known as flex-to-fit, and in this type, flexing is not frequent. Flex circuits are installed to adapt to a particular application in this application. It’s best described as a one-time bending.

Dynamic Applications

In this type, flexing is quite frequent. It is used in applications in which the flexible circuit needs to bent multiple times as part of the application functionality.

In essence, Electronics such as calculators, mobile phones, scanners, cameras, and LCD televisions utilize flex circuits.

They’re used in cardiac monitors, pacemakers, and hearing aids in the medical industry. They’re used to create robotic weapons, sorting robots, and bar code scanners, among other items. Satellites, GPS devices, high-density connectors, high-speed chip-to-chip interconnection, and solar cells all utilize them.

SMT in single-sided PCBs

Single-sided flexible PCBs increase electronic circuit density and performance in PCBs using surface mount technology (SMT).

The advantage of density improvement is multiplied by the use of small electronic components to complement and enhance flex technology’s minimalist packaging ability.

A critical advantage of combining improved density with small parts is better interconnection reliability.

Flexible Integrated Circuits

Combining COB and COF technology allow for optimum interconnection in the smallest possible area.

To minimize electronic packaging interconnection size, the bare IC is packed on the flex circuit in practice. In this field, some of the more popular applications are:

Chip and wire flexible PCB layouts
Tab type or flying lead flexible PCBs
Flexible Flip chip
IC Dense packaging
Stairstep PCB packaging
High-speed cables
Flexible Sensors

Single-Sided Flexible PCB

Flexible Circuits In Medical Products

Although flexible circuits have been used in various items, the most valuable has been their medical devices usage.

They have given life-changing advantages to people with different medical conditions. The use of flex circuits in clinical applications can be classified into the following categories:

Flexible circuits are used as a means of interconnection for the packaging and interconnection of an electronic assembly such as portable monitors and implantable devices.
Flexible circuits are interfacing with the patient to provide diagnostics and therapy.
Hearing aids such as cochlear implants
Ultrasound and RF therapy
Heart disease diagnostics, implants, and treatments such as pulse makers.

Conclusion

A single-sided flexible PCB is the most basic form of a flexible circuit.

On single-sided flex PCB boards, components, wires, sticks, and stiffeners can all be used. Flexible circuits have been utilized in various products, the most valuable of which has been medical equipment.

As opposed to standard cabling and rigid PCBs, single-sided flexible PCBs offer reduced cabling, wiring defects, size reduction, weight reduction, reliability, and durability.

Send Your Inquiry

Your Reliable Single-Sided Flexible PCB Manufacturer in China

SMTFAB is a Professional single-sided flexible PCB supplier in China, and we can provide a one-stop solution for your project.

Over 12 years of single-sided flexible PCB manufacturing experience
Full range of single-sided flexible PCB raw material in stock
100% E-test and final inspection
No minimum order quantity for your new order
24h quick-turn service for your prototype single-sided flexible PCB
7/24 sales and engineering tech support

Send Your Inquiry Now

Production Facility
Flexible PCB Capabilities
1layer Flex PCB Stackup

For flexible PCB capabilities, please refer to the following form.

Feature		Capability
Number of Layers		1 – 10layers
Order Quantity		1pc – 10000+pcs
Board thickness(without stiffener)		0.002-0.2inch
Min. Board Size		0.2*0.4inch
Min. Board Size		9*14 inch
Build Time		2days – 5weeks
Material	FCCL (adhesive)	Shengyi SF305
	FCCL (adhesiveness)	Panasonic R-F775
		Taiflex MHK
		Dupont Pyralux AP
	Coverlay	Shengyi SF305C
		Taiflex FHK 1025&2035
	Adhesive	Taiflex BT
	PI stiffener	Taiflex MHK
	3M	9077&6677&9058
Others	Tolerance of single layer	±0.05mm
	Tolerance of double-layer (≤0.3mm)	±0.05mm
	Tolerance of multi-layer(<0.3mm)	±0.05mm
	Tolerance of multi-layer(0.3-0.8mm)	±0.1mm
	Impedance control tolerance	Single ended:±5Ω(≤50Ω);±10%(>50Ω)
		Differential Pairs: ±5Ω (≤50Ω);±10%(>50Ω)
	Min coverlay bridge	8mil
	Min bend radius of single layer	3-6 times of board thickness
	Min bend radius of double-layer	6-10 times of board thickness
	Min bend radius of multilayer	10-15 times of board thickness
	Min dynamic bend radius	20-40 times of board thickness
Inner layer	Min line width/spacing (12/18um copper)	3.0/3.2mil (loop lines 6.0/6.2mil)
	Min line width/spacing (35um copper)	4.0/4.0mil (loop lines 8.0/8.0mil)
	Min line width/spacing (70um copper)	6.0/6.5mil (loop lines 10/10.5mil)
	Max copper thickness	2oz
Outer layer	Min line width/spacing (18um copper)	3/3.2mil (loop lines 6/6mil)
	Min line width/spacing (35um copper)	4/4.5mil (loop lines 6/6mil)
	Min line width/spacing (70um copper)	6/7mil (loop lines 6/6mil)
	Min line width/spacing (105um copper)	10/13mil (loop lines 6/6mil)
	Max finished copper thickness	3OZ
Drilling	Min distance between via and conductors	6mil (<4 layer)
		8mil (4-6 layer)
		12mil (7-8 layer)
	Min mechanical drill hole	6mil
Solder mask	Solder mask color	Green/White/Black/Yellow
and silkscreen	Coverlay	Yellow、Black
	Min solder dam (base copper ≤ 1OZ)	4mil (green),8mil(solder dam on the large copper)
	Min clearance	3mil (part for 2.5mil)
	Silk color	White, Yellow
Surface treatment	Surface treatment	HASL, ENIG, ENEPIG, Electrolytic Nickel Gold, Soft gold, Hard gold,
		Immersion silver and OSP
	Mixed surface treatment	ENIG+OSP, ENIG+G/F
	Gold thickness (ENIG)	0.05-0.10um
	Nickel thickness (ENIG)	3-6um
	Gold thickness (ENEPIG)	0.05-0.10um
	Palladium thickness (ENEPIG)	0.05-0.15um
	Nick thickness (ENEPIG)	3-6um
	Electrolytic nickel thickness	3-6um
	Electrolytic gold thickness	0.05-0.10um
	Hard gold thickness (including lead)	0.1-1.5um
	OSP thickness	0.1-0.3um
	Immersion silver thickness	0.2-0.4um
Routing	Laser accuracy	±0.05mm
	Punch accuracy	±0.05mm–±0.15mm