Capacitive Switches
Working voltage ≤50V (DC)
Working current ≤100mA
Contact resistance 0.5~10Ω
Insulation resistance ≥100MΩ (100V/DC)
Substrate withstand voltage 2KV (DC)
Rebound time ≤6ms
Insulation voltage 100V/DC
Reliability service life 1 million times
Close displacement 0.1~0.4mm (non-tactile type) , 0.4~1.0mm (tactile type)
Migration of conductive 10MΩ/50VDC between two wires after 56 hours at 55℃, temperature 90%
Working temperature -20℃~+70℃
Storage temperature -40℃~+85℃, temperature 95%±5%
Materials PET ,PC,PMMA, Metal or other materials as per your requirements
Colour Pantone and RAL color matching system
Adhesive 3M, Nitto, Tesa, etc…
Printing Screen Printing, Digital Printing, UV Printing
Thickness of Epoxy 0.25~10.0mm

What is a “Capacitive Switch”?

“Capacitive Switches” is a switching device based on the principle of capacitance change, also known as capacitance sensors or capacitive keys. They are used in a wide range of electrical, medical and industrial devices, especially in applications that require elegant, reliable and sealable solutions, but do not require full touch panel functionality.
Capacitance switches work by detecting changes in capacitance between an object (usually a human body, especially a finger) and the surface of the switch. When the user’s finger approaches the surface of the switch, the capacitance value on the switch surface is changed, and this change is detected by the electronic components of the switch and registered as a touch. Therefore, the capacitor switch can be triggered without physical contact and has the characteristics of no contact and no mechanical parts.

 

Features & Benefits of Capacitive Switch Include:

Product Features

Non-contact operation: Capacitive switches detect the presence of conductive objects, such as fingers, without the need for physical contact. This allows for a clean and hygienic user interface.

High sensitivity: Capacitive switches are so sensitive that they can detect even small changes in capacitance caused by the proximity of fingers or other conductive objects.

Durability and longevity: With no moving parts, capacitive switches are extremely durable and can withstand millions of activations without wearing out.

Design flexibility: Capacitive switches can be easily integrated into a variety of surfaces and materials, including glass, plastic and metal, resulting in a seamless and stylish design.

Water and dust resistance: The non-contact nature of capacitive switches gives them inherent water and dust resistance for use outdoors or in harsh environments.

Customizable sensitivity: Some advanced capacitive switches allow for customized sensitivity levels, allowing designers to fine-tune the response to suit a specific application.

Integrated lighting: Many capacitive switches come with an integrated backlight, which improves visibility in low light environments and adds to the overall aesthetic appeal.

Easy integration of electronics: capacitive wwitches can be easily integrated with microcontrollers and other electronic components to create complex user interfaces.

Product Benefits

Improved User experience: The smooth, seamless and intuitive operation of capacitive switches enhances the overall user experience.

Increased durability: The lack of moving parts and inherent resistance to wear means capacitive switches last longer and require less maintenance.

Enhanced hygiene: The non-contact nature of capacitive switches minimizes the risk of contamination, making them ideal for applications where hygiene is critical, such as medical devices.

Reduced cost of ownership: The lifetime and low maintenance requirements of capacitive switches translate into reduced cost of ownership over the life of the product.

Increased design flexibility: The ability to integrate capacitive switches into a variety of surfaces and materials allows for more creative and innovative designs.

Scalability: Capacitive switches can be easily scaled up or down to suit different applications, from small handheld devices to large industrial control panels.

Energy efficiency: Some capacitive switches feature low power consumption, which contributes to overall energy efficiency and reduced operating costs.

 

How Are Capacitive Switch Constructed?

Panel layer:

The panel is the “coat” of the entire membrane switch, which is not only the interface for users to interact with the switch, but also plays the necessary decorative role.

The panel layer identifies different functions through different colors, patterns, and key shapes, while having a certain degree of elasticity and collapsibility, so that users can press easily.

Insulation layer:

It is located under the panel layer to isolate and protect the circuit.

The insulation layer is usually made of materials with high insulating properties to ensure the safety and stability of the circuit.

Induction layer (capacitance layer) :

This is the core part of the capacitive membrane switch, which contains one or more sets of capacitive electrodes.

When the user’s finger or other conductive object approaches or touches the inductive layer, it changes the capacitance value between the capacitor electrodes, which triggers the switch action.

Circuit layer:

The circuit layer is the electronic component layer in the membrane switch, including the conductive circuit and the necessary electronic components.

It is responsible for receiving the signal from the induction layer and converting it into an electrical signal for processing and transmission.

 

What Special Features Can Be Incorporated into Capacitive Switch?

Certain advanced capacitive switches may also employ more complex structures, such as suspended metal membrane structures manufactured by micro-electro-mechanical system (MEMS) technology, to further improve the performance and reliability of the switches.

The design and optimization of these special structures is usually based on a large amount of simulation and experimental data to ensure that capacitive switches have excellent performance in a specific operating frequency and environment.

 

BX Panel Capacitive Switch Technical Information

  1. The design phase

Demand analysis: According to customer needs and product functions, determine the size, layout, color and pattern of the switch.

Drawing design: Draw detailed design drawings of capacitive switch, including panel pattern, circuit layout, induction layer design, etc.

Material selection: According to the design requirements and product characteristics, select the appropriate film materials (such as PET, PC, etc.), conductive ink, insulating materials, etc.

  1. Plate making and preparation stage

Make screen printing plate: According to the design drawing of capacitive switch, make the screen printing plate required for each printing step. This includes panel pattern plate, circuit plate, etc.

Modulation ink: According to the film material and printing requirements, the appropriate conductive ink and ordinary ink.

Prepare printing equipment: debug and prepare printing machines, screen screens, scrapers and other printing equipment to ensure that the equipment is in good condition.

Three, printing stage

Printing panel layer: Printing background pattern, text logo and other information on the bottom layer of the film material. This step is usually printed with ordinary ink.

Printed circuit layer: The circuit contacts are printed on another film layer, and the circuit pattern is printed by a screen printing process using conductive ink. This step is key for capacitive switch, as the printed quality of the circuit contacts directly affects the performance of the switch.

Printed insulation: Insulation is printed where needed to protect the circuit and prevent short circuits.

Drying treatment: After each layer of printing, the material needs to be dried in a drying oven or tunnel furnace to ensure that the ink is fully cured and firmly attached to the film.

  1. Assembly

Laminated composite: The various films that have been printed and dried are precisely aligned according to the functional order, and then laminated composite is carried out by a hot press in a dust-free environment to form a multi-layer structure of the film switch assembly.

Die cutting: The use of high-precision laser cutting machine or die punching machine to cut the composite film material into the shape and size of the final product, while forming a tactile bump or depression in the key part.

Assembly components: Connect and assemble the capacitive switch with other electronic components (such as circuit boards, wires, etc.) as required.

  1. Back adhesive

According to the use of the product environment and requirements, choose the appropriate type of back adhesive, such as waterproof, temperature resistance, super bonding, etc. We offer 3M, Crown, Soken, Nitto, Sony, Luxking and other adhesive brands

 

What Industries Use Capacitive Switch?

Capacitive switches have a wide range of applications in a number of areas, including but not limited to:

Household appliances: Touch buttons and sliders in consumer electronics such as smartphones, tablets and smart TVS.

Medical devices: In medical devices that require precise control and reliability, capacitive switches can provide an excellent way to interact.

Industrial automation: capacitive proximity switches, as a non-contact sensor device, are also widely used in the field of industrial automation. They can detect the approaching or departing state of an object and convert that signal to an on-off state, enabling automated control.

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